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English Pages [542] Year 1873
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THE PHYSICAL GEOGRAPHY OF THE SEA.
LIEUTENANT
M. F.
MAURY,
LL.D.
i^^^^N-
T.
LONDON: NELSON AND SONS, PATERNOSTER ROW; KI;INBURGH
;
AND NEW YOKK.
&c Digitized by the Internet Archive in
2010 with funding from University of Toronto
http://www.archive.org/details/physicalgeograpOOmaur
miRODUCTIOX TO THE FIRST EDITTOX-1855.
The primary
object of " Tlie
which has grown Sea,
was
Wind and Current
this Treatise
Charts," out of
on the Physical Geography of the
to collect the experience of every navigator as to the
winds
and currents of the ocean, to discuss his observations upon them, and then to present the world with the improvement of commerce and navigation.
By
putting
down on a
same voyage, but
results
chart the tracks of
on charts for the
many
vessels on the
and during
at different times, in different years,
all
and by projecting along each track the winds and currents daily encountered, it was plain that navigators hereafter, by consulting this chart, would have for their guide the results of the combined
seasons,
.experience of all whose tracks were thus pointed out.
Perhaps
it
given port,
might be the
when
his
own
first
voyage of a young navigator to the
personal experience of the winds to be
would
expected, the currents to be encountered by the way,
blank
If so, there
would be the Wind and Current Clwrt.
itself
It
be
wuuld
spread out before him the tracks of a thousand vessels that had pre-
ceded him on the same voyage, wherever at the
same season of the
year.
it
Such a
might
chart,
be,
it
and
was
that, too,
held,
would
show him not only the tracks of the vessels, but the experience also of each master as to the winds and currents by the way, the temperature of the ocean, and the variation of the needle.
All this could
be taken in at a glance, and thus the young mariner, instead of groping his
way
along until the lights of experience should come to
by the slow teachings
of the dearest of
aU
schools,
would here
him find
had already the experience of a thousand navigators guide him on his voyage. He might, therefore, set out upon his
at once that he to
first
voyage with as much confidence in his knowledge as to the winds
and currents he might expect to meet with, as though he himself had already been that
way
a tliDUsand times before.
INTRO DUCTTON TO FIRST EDITION.
IV
Such a chart could not
fail to
masters, and such a chart to sea, they tried
and
it,
with the knowledge
it
commend
itself to intelligent ship-
was constructed
to their surprise
afforded, the
for
They took
them.
and delight they found
it
that,
remote corners of the earth were
many
brought closer together, in some instances by
days'
sail.
passage hence to the equator alone was shortened ten days.
The
Before
commencement of this undertaking, the average passage to Caliwas 183 days but with these charts for their guide, navigators have reduced that average, and brought it down to 1.35 days.
the
fornia
;
Between England and Australia, the average time these charts,
same
going, without
ascertained to be 124 days, and coming, about the
is
making the round voyage one of about 250 days on the These charts, and the system of research to which they
;
average.
have given nearer by
bid fair to bring that colony and the mother country
rise,
many days,—reducing
in
no small measure the average
duration of the round voyage.*
At
the meeting of the British Association of 1853,
member,
a distinguished
meeting in 1854,
its
mated that
this
and embodied describing,
—and
—that in
was
it
stated
by
was again repeated at Bombay, whence he came, it was estithe statement
system of research,
if
extended to the Indian Ocean,
in a set of charts for that sea,
would produce an annual saving
such as I have been
to British
commerce, in
those waters alone, of one or two millions of dollars ;t and in
all seas,
of ten million.s.t *
The outward passage,
average, and the
it
has since been ascertained, has been reduced to 97 days on the
homeward passage has been made
t See Inaugural Address of the Earl of
twenty-fourth meeting.
its
t
.
.
.
"Now
let
us
in 63.
Harrowby, President of the British Association,
make
a calculation of the annual saving to the commerce of the
According to Mr. Maury, the
United States effected by those charts and sailing directions. average freight fi'om the United States to Rio Janeiro tralia.
at
Livei^pool, 1854.
20 cts.; to California, also, about 20
cts.
per ton per day; but (o be within the mark,
we
17.7 cts. per ton per day; to Aus-
is
The mean will
take
of this
it
at 15,
is
a
little
over 19 cents
and include
all
the porta
of South America, China, and the East Indies.
"The
sailing directions
above-named ports "
We
have shortened the passages to California ^0 days,
The mean
to Rio Janeiro 10.
of
of this
South America,
is
20,
Chin;i,
but we
will
take
and the East
it
at 15,
to .\ustralla 20,
and also include the
Indies.
estimate the tonnage of the United States engaged in trade with these places at
1,000,000 tons per
annum.
" With these data, we see that there has been effected a saving
for
each one of theae tons
INTRODUCTION TO FIRST EDITION.
A
system of philosophical research which
and abundant with promise, could not and commend
so rich with fruits
is
to attract the attention
itself to the consideration of the seafaring
of the whole civilized world.
was the
fail
It
experience of
result of the
many
observant men,
and patiently discussed.
brought together for the
first
human knowledge with
its
in attractions to
The
regard to the sea
right-minded men.
results of the first cliart, however,
factory,
was
time,
it
;
now
wonders, and therefore the system of research coidd not be
wanting
The
community
was founded on observation
results tended to increase
and
V
though meagre and unsatis-
were brought to the notice of navigators; their attention
called to the blank sjiaces,
and the importance of more and
ter observations than the old sea-logs generally contained
bet-
was urged
upon them.
They were
told that if each one
would agree
to co-operate in a
general plan of observations at sea, and would send regularly, at the
end of every
an abstract log of their voyage to the National
cruise,
Observatory at Washington, he should, for so doing, be furnished, free of cost,
with a copy of the charts and sailing du-ections that
might be founded upon those observations.
The
quick, practical
mind of the American shipmaster took hold To him the field was inviting, for he
of the proposition at once.
saw
in it the
promise of a rich harvest, and of
So, in a little while, there
many
useful results.
were more than a thousand navigators
engaged day and night, and in
all
parts of the ocean, in
making and
recording observations according to a uniform plan, and in further-
ing this attempt to increase our knowledge as to the winds and ciurents of the sea, and other
phenomena that
relate to its safe navi-
gation and physical geography.
To have
enlist the service of tlie
attention of so
such a large corps of observers, and to
many
clever
and observant men directed
tc
of 15 cents per day for a period of 15 days, whieh will Kive an aggregate of 2,250,000 dollars
saved per annum.
This
is
on
other parts of the world
is
also left out of the calculation.
and
tlie
also the fact that there is a vast
and the United
States,
and
nmonnt"— Extract fi-om
it
will
outward voyage alone, and the tonnage trading with
amount
Take these
all
into consideration,
of foreign tonnage trading between these places
be seen that the annual
sum saved
Hunt's Merchant's Magazine, May, 1S54.
will
sweU
to
an enonnoua
INTEODLXTION TO FIRST EDITION.
VI
the same subject,
was a great point gained
:
it
was a giant
the advancement of knowledge, and a great step toward
stride in
its
spread
upon the waters. Important results soon followed, and great discoveries were made. These attracted the attention of the commercial world, and did not escape the notice of philosophers everywhere.
The
field
was immense, the harvest was
plenteous,
both need and room for more labourers. should gather, or the merest gleaner of of
commerce and navigation
—the
collect,
and there were
Whatever the reapers was to go to the benefit
increase of knowledge
—the good
all.
who
Therefore, all
use the sea were equally interested in the
The Government of the United
undertaking.
States, so considering
the matter, proposed a uniform system of observations at sea, and invited all the maritime states of Christendom to a conference
upon
the subject.
This conference, consisting of representatives from France, England, and Russia, from Sweden and Norway, Holland, Denmark, Belgium, Portugal, and the United States, met in Brussels, August 23, 1853, and recommended a plan of observations which should be followed
on board the vessels of
all
friendly nations,
and
especially of those
there present in the persons of their representatives.
Holy See, the free city of HamBremen and Chili, and the empires of Austria
Prussia, Spain, Sardinia, the
burg, the republics of
and
Brazil, have since offered their co-operation also in the same plan. Thus the sea has been brought regularly within the domains of
philosophical research, and crowded with observers.
In peace and in war these observations are to be carried on in case
;
any of the vessels on board of which they are conducted
be captured, the abstract log observations
is
is
is
of opinion that the results already obtained
to be held sacred.
from this system of research are department of
science,
graphy OF THE
the journal which contains these
—
called
Baron Humboldt
—as
and,
may
Sea.
sufficient to give rise to
which he has If so
called the
much has
by one nation, what may we not expect, lYum the joint co-operation of so many?
a
new
Physical Geo-
already been accomplished
in the course of a
few yeara,
INTRODUCTION TO FIRST EDITION. Rarely before
Vll
there been such a sublime spectacle presented
lias
to the scientific world
:
all
nations agreeing to unite and co-ope-
rate in carrying out one system of philosophical research with regard
Though they may be enemies
to the sea.
in all else, here they are
Every ship that navigates the high
to be friends.
charts and blank abstract logs on board,
seas,
may henceforth
with these be regarded
The instruments
as a floating observatory, a temple of science.
used by every co-operating vessel are to be compared with standards that are
common
to all; so that
anywhere, and in any ship, all
similar observations
by
may be
all
an observation that
other ships in
all
this extensive
admirable system includes will relate only to the
The plan should include the land
made'
parts of the world.
But these meteorological observations which enough.
is
and compared with
referred to
also,
This
sea.
and be
is
and not
universal.
Other great interests of society are to be benefited by such extension
no
less
than commerce and navigation have been.
A
series of sys-
tematic observations, directed over large districts of country, nay, over continents, to the improvement of agricultural and sanitary meteorology, would, I have no doubt, tend to a development of
many The
interesting, important,
agricultural societies
and valuable of
many
results.
states
of
the
Union have
addressed memorials to the American Congress, asking for such extension
;
and
it
is
hoped that that enlightened body
will not fail
favourably to respond.
This plan contemplates the co-operation of
tendom, at least so
far as the form,
all
the states of Chris-
method, subjects of observations,
time of making them, and the interchange of results are concerned.
my
and co-operate The Secretary of the Navy, taking the enlarged and enlightened views which do honour to great statesmen, has officially recommended the adoption of such
I
hope that
in
fellow-citizens will not fail to second
such a humane, wise, and noble scheme.
a system, and the President has asked the favourable consideration Tliese researches for the land look not only to thereof by Congress. the advancement of the great interests of sanitary and agricultural
meteorology, but they involve also a study of the laws which regulate the
atmosphere, and a careful investigation of
Another beautiful feature
in this
system
is,
all its
phenomena.
tJiat it costs
nothing
—
—
INTRODUCTIOX TO FIRST EDITION.
VUl
The instruments that
additional.
these observations at sea call for
are such as are already in use on board of every well-conditioned
and the observations that are required are
ship,
precisely those
which
are necessary for her safe and proper navigation.
Great as
what has been accomplished
the value attached to
is
by these researches,
in the
way
of shortening passages and lessening
the dangers of the sea, a good of higher value
many
is,
in the opinion of
seamen, yet to come, out of the moral, the educational in-
fluence
which
tliey are calculated to exert
A very
munity of the world.
upon the seafaring com-
clever English shipmaster, speaking
recently of the adva,ntages of educational influences
who "
intend to follow the sea, remarks
To the
cultivated lad there
enters on his first voyage.
by
perceive, year
As
a
is
among
those
:
new world spread
out
when he
his education has fitted, so will he
year, that his profession
with things new and instructive.
makes him acquainted
His intelligence will enable him
to appreciate the contrasts of each country, in its general aspect,
manners, and productions, and in modes of navigation adapted to the character of coast, climate, and rivers.
on the phases of the ocean,
terest
breeze,
and
—the
He
will dwell with in-
storm, the calm, and the
will look for traces of the laws
which regulate them.
All this will induce a serious earnestness in his work, and teach to view lightly those irksome
and often
him
offensive duties incident to
the beginner."*
And
that
these
researches
hearted mariners have
have such an
testified.
eS'ect,
many
noble-
Captain Phinney, of the American
ship Gertrude, writing from Callao, January 1855, thus expresses
himself:
" Having to proceed from this to the Chincha Islands, and remain three months,
I avail
myself of the present opportunity to forward to
my two passages over your southern routes, although do so until my own return to the United States next
you abstracts of not required to
•
"The Log
Officers
of a
Merchant
Offlcev,
viewed
witli
and the Youth of the Merchant Semce.
reference to the Education of
By Robert Methren, commander
Young in
tlia
Peninsular and Oiiental Company, and author of the 'NaiTative of the Blenheim Hurricane of 1851."'
London: John Weale, 59
Ackermnn and
Co., Strand.
1851.
Iligli
Ilolboni;
Smith, Elder, and Co., CoruhiU;
INTRODUCTION TO FIEST EDITION. summer, knowing that you are
amply supplied with
less
voyages over these regions than of and, such as
it is,
I
am happy to
ing you with material to
IX
many
contribute
work out
still
abstracts of
other parts of the ocean
my
;
mite toward furnish-
farther toward perfection
your great and glorious task, not only of pointing out the most speedy routes for ships to follow over the ocean, but also of teaching us sailors to look about us, and see by what wonderful manifestations of the
wisdom and goodness of the
great
God we
are continually sur-
rounded. "
For myself,
manded a
I
am
ship, and,
many
free to confess that for
years I com-
although never insensible to the beauties of
nature upon the sea or land, I yet feel that, until I took up your
work, I had been traversing the ocean blindfolded. I did not
know
works of
Him whom
I did not think
the amazing and beautiful combination of
you so beautifully term
'
all
The Great
;
the
First
Thought.' " I feel that, aside from any pecuniary profit to myself from your labours,
you have done me good as a man.
You have
taught
me
to
look above, around, and beneath me, and recognise God's hand in
every element by which I personal benefit.
your work, cause in
in
my
although
am
surrounded.
Your remarks on
me
am
I
grateful for this
this subject, so frequently
feelings
made
of the greatest admiration,
capacity to comprehend your beautiful theory
is
very
limited.
"
The man
letter of this kiud)
fore
spoken as
know how
all
will not be displeased
much
of
might be termed irrelevant matter.
I
I feel,
to excuse, so
what
fail
to
good men, whether ashore or
(in t
have there-
and with sentiments of the greatest
Sentiments like these cannot
from
you express
of such sentiments as
with, or, at least, will
respect."
meet with a hearty response afloat.
Never before has such a corps of observers been enlisted in the cause of any department of physical science as is that which is now about to be engaged in advancing our knowledge of the Pliysical
Geography of the Sea, and never before have men
felt
such an interest
with regard to this knowledge.
Under v.iuds
this
term will be included a philosophical account of the
and currents of the sea
;
of the circulation of the atmosphere
INTRODUCTION TO FIRST EDITION.
X and ocean that
of the temperature
;
hidden in
lie
themselves at the sea and
depths
its
of the wonders and of the phenomena that display ;
In short, I shall treat of the economy of
its surface.
adaptations
its
and depth of the sea
;
—of
waters, its climates, and
its salts, its
and of whatever there may be of general
its
inhabitants,
its
commercial uses or industrial pursuits, for
Physical Geography. The object of this little book, moreover,
all
interest in
such things pertain
to its
and from time
state,
is
to
to time the progress, of this
show the present
new and
beautiful
system of research, as well as of this interesting department of science this
and the aim of the author
;
new
field in
is
may
a manner that
to present the gleanings
from
be interesting and instructive
to all, whether old or young, ashore or afloat, who desire a closer look into " the wonders of the great deep," or a better knowledge as to its winds, its adaptations, or its Physical *
There
is
Geography.*
an old and very rare book which treats upon some of the subjects
this little worli relates:
it is
Description of the Seas."
by Count
L. F. Mai'sigli, a
The copy
to
which
I refer
Frenchman, and
is
called
to
which
"Natural
was translated into Dutch by Boer-
haave, in 1786.
The French count made his observations along the coast of Provence and Languedoc The description only relates to that part of the Mediterranean. The book is divided into four chapters;— the third,
He
first,
on the bottom and shape of the sea; the second, of sea water; the
on the movements of sea water; and the fourth, of sea divides sea water into surface
more than
surface water (not
and deep-sea water
plants.
because,
;
when he makes
salt
from
half a foot below the upper strata), this salt will give a red
colour to blue paper, whereas the salt fiom deep-sea water will not alter the colour at
all.
The reason why
this
The blue paper can only change acid (iodine?)
found
is
its
in surface
colour by the action of an acid.
and not
but he supposes that the saltpetre that
and the motion of the waves, in
the
air, to
be conveyed
earth's cnist, as saltjietre
it
is
is
in deep-sea
water
is, it is
derived from the air;
found in sea water, by the action of the sun's rays
deprived of
its
coarse parts, and, by evaporation, embodied
to beasts or plants for their existence, or deposited
occurs on the plains of Hungary, where the earth absorbs so
upon the
much
of this
vapour.
Donati, also, was a valuable labourer in this to conclude that there are, " at the
field.
His inquiries enabled Mr. Trembley'
bottom of the water, mountains,
plains, valleys,
and
caverns, just as upon the land."
But by
far the
the Mediterranean
most interesting and valuable book touching the physical geography of a Memoir, is Admiral Smyth's List work, entitled "The Mediterranean
Physical, Historical,
*c.
London
:
;
and Nautical. By Kear-Admiral William Henry Smyth,
John W. Parker and '
Son.
1S54.
Philosophical Transactions.
K.S.F., D.C.L.,"
LNTRODUCTION TO THE SIXTH EDITION,
The department of research
Geography of the Sea
of the Physical
there
:
great activity in
is
author of this work to keep
its
it
and
;
it
is
is
a new
up with the improve-
readers posted
made
ments, the developments, and the contributions that are this interesting field
The present
from time
edition contains
field
the aim of the
in
to time.
much that much
has been most carefully revised,
new
is
—
of
;
for the fifth edition
has been recast and
it
some parts omitted.
The
desire
that this
is,
work
shall
keep pace with the progress of
may be supposed, facts are sometimes misinterpreted understood when first developed. Whenever subsequent As
research.
or not
it
research shows such to have been the case, I have not hesitated to tear
down whatever
of conjecture or theory
may have been
built
oa
unstable foundations, and to reconstruct according to the best lights. It
is
proper to say, that, in accounting for the various phenomena
that present themselves, 1
am wedded
to
no theories, and do not
advocate the doctrines of any particular school. Therefore,
when
offered touching
given up the
the explanation which I
any
is
at
my
object.
any time
facts fails to satisfy further developments,
moment one
is
instance that theory
is
system of
old,
preferred which
number of known
it is
suggested which will account for the
new, and equally as well for the
greatest
Tnith
may have
facts.
is
facts.
In every
reconcilable with the
The chapter
of the Gulf Stream
has been enriched with the results of recent investigation, and the theory of the
it
further developed
Open Sea
several others
;
so, also,
that on the Salts of the Sea,
in the Arctic Ocean, the ;
Basin of the Atlantic, and
but these especially have been greatly improved.
INTRODUCTION TO SIXTH EDITION.
Xll
A
separate chapter
is
now devoted
to the
Land and Sea
Breezes,
and extensive contributions have been made to that on Monsoons, Trade Winds, and Cj'clones. has helped I
will,
am
me
Lieutenant Jansen. of the Dutch Navy,
to enrich these with his fine thou^lits.
sure, feel as I do, deeply indebted to
him
The reader for so
much
matter, set forth in his very delightful and pleasing
instructive
manner. National Observatory, WAsniNGrat,
«
Apiil, 1856.
Since the above date, explorations have been
made
in
this
and new veins of precious ore have not yet gone deep enough into
interesting department of science,
We
have been hit upon.
them
to justify a final report.^
In 1849 Congress passed an Act requiring the Secretary of the to employ three small vessels in assisting me to perfect my discoveries. A few weeks ago, Lieiitenant Berryman put to sea
Navy
in
the " Arctic " on this
His attention was especially
duty.
directed to deep-sea soundings along the great telegraphic plateau stretching from
Newfoundland
are of the highest interest.
to
The
Ireland.
Among them
line of volcanic cinders along a line a
is
results, so far,
the discovery of a
thousand miles in length,
and reaching entirely across the Gulf Stream where the submarine telegraph
There
is is
to cross
it.
upon Ozone, upon the cuxulation of the atmo-
also Lieutenant Jansen's experiments
which cast unexpected
light
sphere.
Matter of more general or higher that contained in this fields
new Edition
is
scientific
importance than
seldom gathered from any
of research,
December, 1S5G.
'
Vide subsequent additions in the present Edition, Chapters xxi. xiii.
EXPLANATION OF THE PLATES.
a diagr im to illustrate the circulation of the atmosphere (Chap. the circumference of the circle are belts, and prevailing direction of the wind on each intended to The arrows exterior to the periphery of the circle— section of those belts. which is a section of the earth supposed to be made in the plane of the meridian are intended to show the direction of the upper and lower strata of winds in the general system of atmospherical circulation and also to illustrate how the air brought by each stratum to the calm belts there ascends or descends, as the case may be and then, continuing to flow on, how it crosses over in the direction in which it was travelling when it arrived at the calm zone. Plates II. and III. are drawings of Brooke's Deep-sea Sounding Apparatus, for bringing up specimens of the bottom (g 701). Plate IV. is intended to illustrate the extreme movements of the isotherms The connection be50°, 60°, 70°, &c., in the Atlantic Ocean during the year. tween the law of this motion and the climates of the sea is exceedingly interesting. Plate V. is a section taken from one of the manuscript charts at the Observatory. It illustrates the method adopted there for co-ordinating for the Pilot For this purpose the ocean Charts the winds as reported in the abstract logs. usually five degrees of latitude by five deis divided into convenient sections, These parallelograms are then subdivided into a system of grees of longitude. engraved squares, the months of the year being the ordinates, and the points of As the wind is reported by a vessel that passes the compass being the abscissas. through any part of the parallelogram, so it is assumed to have been at that time From such investigations as this the Pilot Charts all over the parallelogram.
Plate
III.).
is
I.
The arrows and bands within show the calm
—
;
;
—
(§ 929) are constructed. Plate VI. illustrates the position of the
channel of the Gulf Stream (Chap. I.) winter. The diagram A shows a thennometrical profile presented by cross-sections of the Gulf Stream, according to observations made by the The elements for hydrogx-aphieal parties of the United States' Coast Survey. this diagram were kindly furnished me by the superintendent of that work. They are from a paper on the Gulf Stream, read by him before the American Association for the Advancement of Science, at its meeting in Washington, 1854. Imagine a vessel to sail from the Capes of Virginia straight out to sea, crossing the Gulf Stream at right angles, and taking the temperature of its waters at the surface and at various depths. The diagram shows the elevation and depression of the thermometer across this section as they were actually observed by such a for
summer and
vessel.
The black lines x, y, z, in the Gulf Stream, show the course which those Tlie lines a, b, show the computed drift threads of warm waters take (§ 57). route that the unfortunate steamer San Francisco would take after her terrible December 1853. Plate VII. is intended to show how the winds may become
disaster in
geological agents.
It shows where the winds that, in the general system of atmospherical circulation, blow over the deserts and thirsty lands in Asia and Africa (where the
annual amount of precipitation is small) are supposed to get their vapour; and where, as surface winds, they are supposed to condense portions of it whither they are supposed to transport the residue thereof through the upper regions, retaining it until they again become surface winds. Plate VIII. shows the prevailing direction oi' the wind during the year in all ;
EXPLAXATION OF THE PLATES.
XIV
parts of the ocean, as derived from the series of investigations illustrated on Plate YII. It also shows the principal routes across the seas to various places. Where the cross-lines representing the yards are oblique to the keel of the vessel, they indicate that the winds are, for the most part, ahead when perpendicular The figures on or near or square, that the winds are, for the most part, fair. the diagrams representing the vessels, show the average length of the passage in days. The arrows denote the prevailing direction of the wind ; they are supposed to The half-bearded and so that the wind is going as the arrows point. fly u-ith it half-feathered arrows represent monsoons (§ 763), and the stippled or shaded belts the calm zones. In the regions on the polar side of the calms of Capricorn and of Cancer, where the arrows are flying both from the north-west and tlie south-west, the idea intended to be conveyed is, that the prevailing direction of the winds is between the uorth-west and the south-west, and that their frequency is from these two quarters in proportion to the number of arrows. Plate IX. is intended to show the present state of our knowledge with regard to the drift of the ocean, or, more properly, with regard to the great flow of polar and equatorial waters, and their channels of circulation as indicated Ly the thermometer (§ 8S9). Further researches will enable us to imjirove this chart. The most favourite places of resort for the whale—ric/Ai in cold, and sperm in warm water are also exhibited on this chart. Plate X. exhibits the actual path of a storm, which is a type (§ 85) of the West Indian hurricanes. Mr. Redtield, Colonel Eeid, and others, have traced out the paths of a number of such storms. All of this class appear to make for the Gulf Stream after reaching it, they turn about and follow it la their course ;
;
—
:
(S 95).
Mr. Piddington of Calcutta has made the East Indian hurricanes, which are similar to these, the object of special, patient, and laborious investigation. He calls them ci/clones, and has elicited much valuable information concerning them, which may be found embraced in his "Sailor's Horn-huok," "Conversations about Hurricanes," and numerous papers published from time to time in the Journal of the Asiatic Society. Plates XI. and XII. speak for themselves. They are orographic for the North Atlantic Ocean, and exhibit completely the present state of our knowledge with regard to the elevations and depressions in the bed of the sea Plate XII. exhibiting a vertical section of the Atlantic, and showing the contrasts of its bottom with the sea-level in a line from Mexico across Yucatan, Cuba, San Domingo, and the Cape de Verds, to the coast of Africa, marked A on Plate XI. Plate XIII. The data for this Plate are furnished by Maurj''s Storm and Rain Charts, including observations for 107,277 days in the North Atlantic, and 158,025 in the South; collated by Lieutenant J. J. Guthrie, at the Washington Observatory, in 1855. The heavy vertical lines, 5', 10°, 15°, &c., represent parallels of latitude; the other vertical lines, months; and the horizontal lines, per cents., or the number of days in a hundred. The continuous curve line stands for phenomena in the North, and the broken curve line for phenomena in the South Atlantic. Thus the Gales' Curve shows that in every hundred days, and on the average, in the month of January of different years, there have been observed, in the uortheirn hemisjihere, 36 gales (36 per cent.) between the jiarallels of 50° and 55° ; whereas during the same time and between the same parallels in the southern hemisphere, only 10 gales on the average (10 per cent.) have been reported. The fact is liere develojied that the atmosphere is in a more unstable condition in the North than in the South Atlantic; that we have more calms, more rains, more fogs, more gales, and more thunder in the northern than in the southern liemisj.here. particularly between the equatur and the 55th parallel. Beyond that the influence of Cape Horn becomes manifest. ;
—
CONTENTS.
Pase
Cbspter I.
II.
III.
The
Gclf Stp.eam
••«
Influence of the Gulf Stream upon Climates
...
...
The Atmosphere
...
...
6l'^7
123
...
...
...
...
...
IV.
Land and Sea Breezes
...
...
...
...
.••
V.
Red Fogs AND Sea Dust
...
...
...
...
...
VI.
VII. Currents OF the Sea
IX.
The Open Sea
IN
...
...
...
...
13o
...
...
...
166
...
...
...
199
...
...
...
...
203
...
...
...
...
249
...
...
264
...
the Arctic Ocean
The Salts of the Ska
...
X. The Equatorial Cloud-Ring
XI. On the Geological Agency of the Winds XII.
35
On the probable relation between Magnetism and the Circulation of the Atmosphere
VIII.
^
...
...
The Depths
OF THE Ocean
XIII. The Basin of the Atlaktio
XIV. The Winds
XV. Climates
...
...
...
...
...
292
...
...
...
...
306
...
...
326 362 331
...
of the Ocean
XVI. The Drift of the Sea
...
...
...
...
...
...
...
...
...
...
XVII. Storms
405
XVIII. Routes
4]3
XIX. Brussels Conference,
XX. Force
of the Trade
etc.
...
...
•••
—
*3*^
Winds of the Southern Hemisphere—
Peculiai.ities in its Atmospheric Circulation
XXI. The Submarine Telegraph OF THE Atlantic
...
...
435
...
4ti9
—
THE
PHYSICAL GEOGRAPHY OF THE SEA.
CHAPTEE
I.
THE GULF STREAM. Us
Colour, §
2.
— Theories, — Captain 5.
Livingston's,
—
6.
— Dr.
Franklin's, 7.
Admiral Smyth and Mediterranean Currents, 8. Trade Winds not the Cause of the Gulf Stream, 9.— Drift of Bottles, 12.— Sargasso Sea, 13.— Hypothetical System of Currents, 19. Galvanic Properties of the Gulf Stream, 26. SaltGulf Effects produced upon Currents by Evaporation, 32. ness of ditto, 29. Stream Roof-shaped, 39. Effects of Diurnal Rotation upon Running Water, 42.— Course of the Gulf Stream not altered by Nantucket Shoals, 52. The Trough in the Sea through which the Gulf Stream flows has a Vibratoij MoStreaks of Warm and Cold Water in the Gulf Stream, 57. Runs tion, 54. up Hill, 59. -A Cushion of Cold Water, 60.
— —
—
—
—
— —
—
There it
never
flows. its
i.s
and
fails,
Its
cmTent
tain,
and
In the severest di'oughts
a river in ihe ocean.
of
is
its
Stream.
flow of water.s.
its
is
is
never over-
it
bottoms are of cold water, while
The Gnlf of Mexico
warm.
mouth
There
sippi or the
in the mightiest floods
banks and
in the Ai'ctic Seas.
in the world
Its current is
Amazon, and
chapteu
its
is its
It is the
form-
stream.
Gulf
no other such majestic
more rapid than the
Missis-
volume more than a thousand
times greater. Its waters, as coasts, are
far out
from
tlie
,
marked, that their
Gulf as the Carolina
They
of an indif'O blue.
line of junction
are
,
with the
so
distinctly
common
sea
§
2
colour of its WBlcra
THE PHYSICAL GEOGRAPHY OF THE
2 cnociprsa
may be may be
water vessel
by the
traced
is
Often one half of the
eye.
perceived floating in Gulf Stream water,
while the other half
sharp
SE.\.
in
is
common water want
the line, and such the
of the sea
so
;
of affinity between
those waters, and such, too, the reluctance, so to speak,
on the part of those of the Gulf Stream to mingle with the
common water
of the sea.
At the salt-works
§ 3
and along the shores
in France,
by
of the Adriatic, where the "salines" are can-ied on
the process of solar evaporation, there or pools through which the water froui
3a;tr.e«..
the sea, and
longer
reduced to the briny
the hue of
is
its blue,
about to commence, when the
puts on a reddish
Stream are which they
passed as
it
The grows,
until crystallization
now
deep blue water
the waters of the Gulf
and hence we can account
indigo blue which
comes
than the watei"S of the sea through
Salter^
flow,
Now
tint.
it
state.
exposed to evaporation the Salter
it is
and the deeper is
is
is
a series of vats
is
all
navigators observe
ofl"
for the
deep
the Carolina
coasts. §
4
These
salt-malcers
are
the
in
of judging
habit
the richness of the sea water in salt
greener the hue, the fresher the water.
by
colour
its
We
—
have in
of
the
this.
an explanation of the contrasts which the waters ^ of the Gulf Stream present with -those of the Atlantic, as
Contrast ])erhaps, ^ i with other waters.
well as of the
Polar waters regions,
and
;
lio'ht
also
o-reen of the
North Sea and other
of the dark blue of the trade-wind
especially of the Indian Ocean,
which poets
have described as the "black waters." §
5
What
is
the
cause
puzzled philosophers.
of the
Many ^
Gulf Stream has always
are the theories
§-29.
and numer-
THE GULF
3
STREA^r.
ous the speculations that have been advanced with regard chapter to
Modern
it.
investigations
ginning to throw some light upon the subject, though is
not yet
the father of the Gulf Stream.
produce
'—
all
clear.
Early writers maintained that the Mississippi Kiver v.-as
—
and examinations are be-
it
;
for its velocit}', it
Its floods,
was
they
held, could be
puted by the rate of the cm-rent of the
said,
cause,
com-
liver.
Captain Livingston overturned this hypothesis by showing that the volume of water which the Mississippi River
empties into the Gulf of Mexico
Theories
§ 6 captain
not equal to the three-
is
thousandth part of that which escapes from
it
through
the Gulf Stream. ]\Ioreover, the
water of the Gulf Stream
of the Mississippi fresh tiiat
just as
much
;
is
salt
—
that
and those philosophers^ forgot
salt as escapes
from the Gulf of Mexico
through this stream, must enter the Gulf through some other channel from the
main ocean
for, if it
;
Gulf of Mexico, in process of time, miless
bed at the bottom, or was fed I'elow fresh
—
neither of which
is
Avith
probable
did not, the
it
had a
salt
salt springs fi'om
—would become
a
water basin.
The above quoted ai-gument
;
and upon the remains
had so completely overturned
of the hypothesis which he
he set up
Captain Livingston,
of
however, was held to be conclusive
another, which, in turn, has been upset.
In
it
he ascribed the velocity of the Gulf Stream as depending 'J
on the motion of the sun
in the ecliptic,
and the
influ-
ence he has on the waters of the Atlantic."
But the opinion that came received and deep rooted in the
»
§5.
to be
mind
the most generally of seafaring peoph^
§
7
THE PHYSICAL GEOGRAPHY OF THE
4 CBAFTER
—
was
One repeated by Dr. Franklin, and
tliB
that the Giilf Stream
'—
SEA.
is
wliicli
held
the escaping of the waters that
lin's opin-"
have been forced into the Caribbean Sea by the trade-
thetraTe-
winds, and that
^'"''*'
it
the pressure of those winds upon
is
the water which forces up into that sea a head, as
it
Avere, for this stream.
"We
know
of instances in which waters have been ac-
cumulated on one side of a lake, or
AA-inds
may
its
tradeinitial
velocity,
but are they of themselves adequate to such an
effect?
To
my
mind, the laws of Hydrostatics, as at
present expounded, appear
Kotcon-
one end of a canal,
give the Gulf Stream
to
assist
in
The pressure of the
at the expense of the other.
conclusion that
it
is,
by no means
to warrant the
unless the aid of other agents also
be brought to bear. §
Admiral Smyth, in
8
teiTanean
(p.
feet Strait of
known
above
its
memoir on the Medi-
162), mentions that a continuance in the
Sea of Tuscany of has been
his valuable
"
gusty gales" from the south-west
to raise its surface
ordinary
no
less
than twelve
This, he says, occasions a
level.
strong surface drift through the Strait of Bonifaccio.
But
tonifaccio
in this
we have nothing
and narrow channel-way
like the
any pond
;
no
deej)
to conduct these waters off like
a miniature river even in that
sea,
but a mere surface
up
of water in
or gulf above the ordinary level.
The Boni-
flow, such
its differ-
Gulf Stream
as usually follows the piling
faccio Current
does not flow like a "river in the sea"
t-cc finm t'ffniit
across the Mediterranean, but
as
it
spreads itself out as soon
passes the Straits, and, like a circle on the water,
loses itself
room.
it
by broad spreading
as soon as
it
finds sea-
THE GULF STREAM.
5
Supposing the pressure of the waters that are forced into the Caribbean Sea
by
cause of the Gulf Stream, that Sea and the Mexican Gulf
much higher
should have a
support "a gi-eat degree of elevation."
immense
its
Major Rennell
river descending from
Now, we know very nearly
a higher level into a plain."
the average breadth and velocity of the Gulf Stream in the Florida Pass.
approximation,
the
We
"
than the Atlantic.
level
Accordingly, the advocates of this theory require for
likens the stream to " an
chapteh
the trade-winds to be the sole
know, with a
also
and breadth of
velocity
waters off Cape Hatteras.
like degree of
same
tlie
Their breadth here
Breadth city in tiie
Pass,
about
is
" seventy-five miles against thui-y-two in the " Nari'ows
of the Straits,
and
their
mean
velocity
is
three knots off
Hatteras against four in the "Narrows."
This being the
off
cap-
Hatter**
case, it is
off
easy to show that the depth of the Gulf Stream
Hatteras
Bernini
is
not so great as
by nearly 50 per
instead of descending,
an inclined
cent.,
in the "
and
uj')
Narrows
" of
that, consequently,
bed represents the surface of
plane, with its descent inclined
toward the south, tlie
its
it is
from the north
which plane the lower depths of
stream must ascend.
If
we assume
its
depth
offitsdeptu offSemJni.
Bemini* to be two hundi-ed fathoms, which are thought to be within limits, the above rates of breadth
city will give one
depth off Hatteras. Straits are
and
hundred and fourteen fathoms
below the
The waters, level
therefore,
velo-
for its
which in the
of the Hatteras depth, so far
from descending, are actually forced up an inclined plane,
its
waters
ascend *
Professor Bache reports that the officers of the Coast Survey have soundei
with the deep sea lead, and ascertained ary, 1856).
its
depth here to be 370 fathoms (Jaui-
THE PHYSICAL GEOGRArHY OF THE
6 CHAPTER
——
.
whose submarine ascent
jrara cun-
trasted
with the
Gulf
not
less
than ten inches to
tlie
mile.
The Niagara
§10 TheNia-
is
SEA.
is
an "immense river descending into
But instead of preserving x o its character in Lake Ontario as a distinct and well-defined stream for several hundred miles, it spreads itself out, and its waters
g^
plain." ^
Stream.
Why
are immediately lost in those of the lake.
not the Gulf Stream do the same true
itself, it is
by broad
but, instead of mingling
;
spreading, as the
into the northern lakes do,
"
with the ocean
immense rivers" descending
its
waters, like a stream of
ocean, preserve a distinctive
in the
should
It gi-adually enlarges
?
oil
more
character for
than three thousand miles. §
Moreover, wliile the Gulf Stream
11
north from there Currents
meeting '^
is '-'
divides
warm
itself,
running to
is
level
at
t];e
the south,
down from the north midway the ocean,
a cold current coming
meeting the it
supposed
its
elevated
;
waters of the Gulf
and runs by the
side of
them right back
into those very reservoirs at the south, to which theory
gives an elevation sufficient to send out entirely across
the Atlantic a jet of warm water said to be more than three
thousand times
gi^eater in
volume than the Mississippi River.
This current from Baffin's
winds to give unfavourable to
below the
And
and and
for a great part of the
far
there
is
If so,
way
beyond the propelling
it is
reacli oi
every reason to believe that
with other polar currents,
to the Gulf Stream.
causes?
trade-
a head, but the prevailing winds are
it,
surfiice,
any wind. this,
it
Bay has not only no
is
quite equal in volume
Are they not the
effects
what have the trade winds
the one more than the other
?
to
of like
do with
THE GULF It
is
custom often
a
7
STIlEiJ^r.
practised
by seafaring people
throw a bottle overboard, with a paper, stating the
to
lime and place at which
it
is
cEiFTEB
—
In the absence of
done.
Infonna-
other information as to currents, that afforded
na\^gators
little
„
.
.
mute
tracks behind them,
is
it
botiies.
and their routes can not
seeing where they are found, some idea as to their course.
tion de-
rived f:tm
They leave no
But knowing where they were
be ascertained.
these
,
of gi-eat value.
is true,
by
Straight lines
may
may
cast,
and
be foi-med
at least be drawn,
showing the shortest distance from the beginning to the
end of their voyage, with the time elapsed. Beechey,
wa}^, the tracks of it,
it
Admiral
has prepared a chart, representing, in
E,.N.,
more than one hundi-ed
appears that the waters from every quarter of the
Atlantic tend toward the Gulf of Mexico and Bottles cast into the sea tlie
tliis eher_
From
bottles.
New
midway between
its
stream.
the Old and
Worlds, near the coasts of Europe, Africa, and
America, at the extreme north or farthest south, liave
been found either in the "West Indies, or the British Isles,
or within the
well-known range of Gulf Stream
waters.
Of two
cast out together in south latitude on the coast
of Afiica, one
was
foilnd on the island of Trinidad
other on Guernsey, in the English Channel.
;
tlie
In the ab-
sence of positive information on the subject, the circumstantial evidence that the latter
the Gulf
is
all
but conclusive.
performed the tour of
And
there
is
reason to
suppose that some of the bottles of the admiral's chart liave also
performed the tour of the Gulf Stream
;
without being cast ashore, have returned with the
Admi-ai
then, drift
along the coast of Africa into the inter-tropical region
;
THE PHYSICAL GEOGRAPHY OF THE
8 OHAPTER thence
—
SEA.
through the Caribbean Sea, and so ou with the
Gulf Stream again.
Another
bottle,
(Plate VI.)
thrown over
off
Cape Horn by an
American master, in 1837, has been recently picked up on the coast of of the
An
Ireland.
inspection of the chart, and
of the other bottles, seems to force the con-
di'ift
clusion, that this bottle too
went even from that remote
region to the so-called hlglier level of the Gulf Stream reservoir. §
Midway
13
the s»-;"»3
is
the Atlantic, in the triangular space between Canaries,
A2K)res,
the Sargasso Sea.
and the Cape de Verd (Plate
Islands,
Covering an area
VI.)
equal in extent to the Mississippi Valley,
it is
so thickly
matted over with Gulf Weeds (fucus natans), that the speed of vessels passing through
When
the companions of
it is
often
Columbus saw
much
it,
retarded.
they thought^
marked the limits of navigation, and became alarmed. To the eye, at a little distance, it seems substantial enough it
to
walk upon.
Patches of the weed are always to be
seen floating along the outer edge of
Now,
of cork or chaff, or
if bits
any
tb.e
Gulf Stream.
floating substance,
be put into a basin, and a circular motion be given to
the water,
all
the
light
substances
crowding together near the centre of the there
is
the least motion.
Just such a
Atlantic Ocean to the Gulf Stream Diuc^ vered by coiMib'js.
Sea
is
this
weedy
the centre
this day,
pool,
basin
and
i\\Q
Columbus
sea in his voyage of discovery
remained to its
of the wliud.
;
;
to
be found
will
where is
the
Sargasso
first
tb.ere
found it
has
moving up and down, and changing
position like the cahns of Cancer, according to the
seasons, the storms,
and the winds.
Exact observationa
THE GULF as to its limits years,
assui'e
and
mean
its
therefore, this
level in
one
be
why
so,
paii: of its
Nay, more
;
is
1-
anV^'si'""*'
bottle
inforaiation.
If,
give the endless current a higher
course than another
at the very season of
the Gulf Stream
for fifty chaptkk
by the
con-oborated
is
and other sources of
Plate VI.,
back
has not been
position
This indication of a circular
motion by the Gulf Stream
by
9
their range, extending
us that
altered since that time.
chart,
STREAir.
?
the year
when
§
14
rushing in greatest volume through
the Straits of Florida, and hastening to the north with
the greatest rapidity, there
is
a cold stream from Baffin's
coia stremii St
Bay, Labrador, and the coasts of the north, running to
Where
the south with equal velocity.
is
the trade-wind
n om
nly
that gives the higher level to Baffin's Bay, or that even ]n-esses
upon, or assists to put this current in motion
The agency of winds in producing currents sea tb.e
of
must be very
These two cuirents meet off
partial.
Grand Banks, where the
bergs,
One part
latter is divided.
underruns the Gulf Stream, as
it
is
shoA^Ti
by the
ice- itsdire>
which are carried in a direction tending across
The probability
course.
?
in the deep
is,
that this
" fork"
its
on
flows
toward the south, and runs into the Caribbean Sea, for the temperatui'e of the water at a
been found far below the crust,
little
depth there Las
mean temperature
and quite as cold as
of the earth's
at a corresponding depth off
the Arctic shores of Spitzbergen.
More water can not run from the equator or pole than to
it.
the Gulf Stream,
If
we make
we ought
produce the Polar flow part,
and
;
tlie
the trade-winds to cause
to have
some other wind
15
currenu
to encedby
but these currents, for the most
for great distances, are
§
submarine, and there-
THE PHYSICAL GEOGRAPHY OF THE
10
CHAPTKR fore bej'ond
the influence of winds.
appear that winds have
little
to
SEA.
Hence
should
it
do with the general
system of aqneous circulation in the ocean.
The other
16
fork"
runs between us and the Gulf
Stream to the south, as already described.
As
has been traced,
it,
vp §
"
it
warrants the belief that
to seek the so-called Jiigher level of the
power
The
necessary
to
overcome
far as
it
too,
runs
Mexican
Gulf.
the
resistance
opposed to such a body of water as that of the Gulf
running
Stream,
thousand
sevei-al
miles without
any
renewal of impvilse from the forces of gi'avitation or any
known cause, is truly surprising. It we have an argument for determinincr,
happens
other
so
that
"n*ith
consi-
Resistance U) the Gull
dcrablc acciu'acy, the resistance which the waters of
^tieara.
stream meet with in their motion toward the to the diurnal rotation, they are carried
earth on
its
around with
tlie
axis toicard the cast with an hoiu'ly velocity
of 07ie hundred
and
fifty-seven* miles gi-eater
enter the Atlantic than
of Xewfoimdland
;
for,
when they
an'ive
ofi'
in consequence of the
of latitude between the parallels of tliese rate of
tliis
Owing
east.
two
motion around the axis of the earth
from nine hundred and
fifteen-]-
to seven
when they the
Banks
difference
places, their is
reduced
hundred and
fifty-eight miles the hour. §
17
Therefore this
we suppose Banks
in
it
immense
to pass
volixrne
of water would,
if
from the Bahamas to the Grand
an hour, meet with an opposing force in the
* In this calculation tLe earth
is
treated as a perfect sphere, with a diameter
of 7925-56 miles.
t Or 915'26 to 758 '60. (»d the latter parallel, the current has an east pet ff about one and a half miles the hour, making the true velocity to the east and on the axis of the earth, about seven hundred and sixty miles an hour at the ;
(irand Baiika.
THE GULF STREAM.
of resistance sufficient, in the aggregate, to retard chapteb
Bliape it
11
two miles and a half the minute in
its
eastvvardly rate.
If the actual resistance be calculated according to received laws,
it
pressure
gentle trade- winds be to such resistance, and to
assigned
we
And
found equal to several atmospheres.
will be
by analogy, how inadequate must the them
tlie effect
therefore, in the proposed inquiry,
If,
?
of the
search for a propelling
higher level of the Gulf,
power nowhere but
we must
the
in
admit, in the head of
water there, the existence of a force capable of putting in motion, and of driving over a plain at the rate of four miles the hour,
all
the waters, as fast as they can be
brought down by three thousand^ such streams as the Mississippi River,
come
tlie
—
a power at least sufficient to over-
resistance required to reduce from
and a half
to a
few
feet per
two miles
minute the velocity of a
stream that keeps in perpetual motion one fomih of
all
the waters in the Atlantic Ocean.
The iect, •>
from observation on
facts,
afford us at best but a
'
no means
sufficient
to
this
interesting sub-
mere glimmer of o
make any mind ^
light, o '
clear as to
of the Gulf, or as to the sufficiency of
hiqJier level ^
_
by J a
any
.
other of the causes generally assigned for this wonderfid stream.
If
it
be necessary to resort to a higher level in
the Gulf to account for the velocity off Hattei'as, I cannot perceive wliy tro
we
should not, with like reasoning, resort
a higher level off Hatteras also to account for the velo-
city off the
throughout reductio
Grand Banks, and thus make the Gulf Stream, its
circuit,
a descending
cui-rent, and,
ad absurdum, show that the
not adequate to the effect ascribed.
by the
trade- winds are
Moreover, the top
§
18
^°^^^tainty as *° "'®
cause of ^^^ ^uif stream.
THE PHYSICAL GEOGRAPHY OF THE SEA
1 2
Gulf Stream runs on a level with the ocean, there-
CHAPTER of the
know
fore ive §
19
When
Let
tration.
having
size,
wanting,
us, therefore,
a
it
often happens that hypo-
the purposes of
in their stead,
serve,
thesis \vill Hj-pothe-
not a descending current.
it is
facts are
solid
illas-
suppose a globe of the earth's
nucleus,
and covered
all
over
with water two hundred fathoms deep, and that every of heat
source that
its fluid
and cause of radiation be removed,
On
throughout.
so
temperatiu-e becomes constant and uniform
such a globe, the equilibrium remain-
ing undisturbed, there would be neither vnnd nor current. §
20
now
Let us tropics, to
becomes
suppose that
disturbed,
rents and counter cm-rents
—
the
oil,
the
and a general system of
poles,
cur-
would be immediately com-
an unbroken sheet on the
in
rimning toward the cuiTent,
the water within
The aqueous equilibrium of the planet
oil.
would thereby be menced
all
the depth of one hundred fathoms, suddenly
surface,
and the water, in an under
The
toward the equator.
oil
supposed, as
is
it
reaches the polar basin, to be reconverted into water^ and tlie
water to become
coi-n,
rising to the
oil
as
it
crosses
Cancer and Capri-
smface in the intertropical regions, and
returning as before. §
21
Thus, without tuind,
we should have
a perpetual and
uniform system of tropical and polar currents. sequence of diurnal rotation of the planet on each particle of
oil,
In conits
axLs,
were resistance small, would approach
the poles on a spiral turning to the east, with a relative velocity gi-eater tlie pole,
and
gi-eater, until
and whirl about
it
finally
it
would reach
at the rate of nearly a tliou-
^
THE GULF
1
Becoming water and
Band miles the hour. velocity, it
STREAil.
would approach the
tropics
by a
inverted spiral, turning toward the west. principle here alluded to, all ciurents
3
losing its chapter
—
similar but
Owing
to the
from the equator to
the poles should have an eastward tendency, and
all
from
the poles toward the equator a westward.
Let us now suppose the thetical globe to
bottom of our size,
nucleus of this hj'po-
solid
and
seas,
and
in all respects, as to figure
to represent the shoals
and islands of the
the coast lines and continents of the
as
22
§
assume the exact form and shape of the
sea, as
earth.
uniform sj'stem of cuiTents just described would
well
The
now
be
Results of
hypothesis
interrupted
by
obstnictions
and
local causes
of various
kinds, such as unequal depth of water, contour of shorelines, &;c.
;
gi'eater in
there to
and we should have at certain places currents
volume and velocity than
and from either pole and the equator.
the cold waters of the north, and the Gulf,
we
But
at others.
still
would be a system of currents and counter currents
made
specifically lighter
by
warm
Now, do not waters of the
tropical heat,
and which
see actually preserving such a system of counter cur-
rents, hold, at least in
supposed water and
oil
some
degi'ee,
the relation of the
?
In obedience to the laws here hinted
at,
there
is
a
constant tendency^ of polar waters toward the tropics, and of tropical waters
toward the
poles.
Captain Wilkes, of
§
23
Tendency and cal
tlie
tropi-
watera
United States Exploring Expedition, crossed one of
these hjqjerborean under-cm-rents
two hundred miles
in
breadth at the equator.
Assuming the maximum velocity at five knots,
and
its
of the Gulf
Stream
depth and breadth in the Narrows ' 1
Plate IX,
§
24
A'^nmea Telocity
THE PHYSICAL GEOGRAPHY OF THE
14 CHAPTER of
Bemini
SEA.
would
before/ the vertical section across
as
present an area of two hundred millions of square feet
moving of'recm^ g:iavity.
The Qf
at the rate of seven feet three inches per second.
difference of
specific
gravity between the volmne
Gulf Water that crosses this sectional line in one
and an equal volume of water
second,
at
ocean
the
temperatiu'e of the latitude, supposing the two volumes to
be equally
salt,
millions
fifteen
is
of pounds.
If
these estimated dimensions (assumed merely for the pur-
mthin
poses of illusti'ation) be
limits,
then the force per
second operating here to propel the waters of the Gulf
toward the pole
tlie
is
equilibrating tendency
due
to
millions of pounds of water in the latitude of
fifteen
This
Bemini.
in one scale of the balance.
is
other, the polar scale, there gi'avity
is
In the
the diflference of specific
due an equal volume of water in the polar basin,
on account of
its
degree of temperature as well as of
salt-
ness. §
25
Author's
In investigating the currents of the
such agencies
seas,
As a
should be taken into account.
cause,
I
doubt
opinion.
whether
one
this
sufficient
is
of
itself
to
produce
a
stream of such velocity and compactness as that of the Gulf;
for,
assuming
the proposition
is
sufficient to
estimated discharge to be correct,
almost susceptible of mathematical de-
inonsti'ation, that to
consequence of
its
its
di"ive,
overcome the resistance opposed in
velocity
would require a
at the rate
force at least
of three miles the hour,
ninety thousand millions of tons
up an inclined plane
having an ascent of three inches to the mile.*
Yet
the very principle from which one of these agents * Supposing there be no resistance from frictiju.
heat, is
de-
;
THE GULF
STREiUr.
1
5
admitted to be one of the chief causes of those chapteh
rived, is
winds which are said
The chemical
to be the sole cause of this cuiTent.
properties, or, if the expression be admis-
of the Gulf Stream waters, the oqalvanic properties IT L come fi-om their fountains, are different, or rather
sible, ^
as they •^
more so,
intense,
they
than they are in sea water generally.
may have
viscosity that
26
chemical properties "^ '« waters.
If
a peculiar molecular aiTangement or
i-esists
tiie
differing in temperature fact,
§
admixtui'e of other sea waters
and
It is a well
saltness.
known
when put in mix of themselves, but Nor do large volumes
that waters of different temperatures,
the same vessel, do not readily require the process of agitation.
of water in motion readily admit of the admixture of
water at
In
18
rest. 4;
3 the Secretary of the
Navy
took measm-es fjr
Experi-
ments on
procuring a series of observations and experiments with
sea water.
regard to the corrosive effects of sea water upon the copper sheathing of ships.
With
these researches were carried
and
it is
patience, care,
on
and labour,
for a period of ten years
said the fact has been established, that the cop-
per on the bottom of ships cruising in the Caribbean Sea
and Gulf of Mexico water upon
it,
suffers
more from the action of sea
than does the
co]->per
anv other part of the ocean. ^
of sliips cruising in
In other words, the
salts
Oai'^an'c
propertied
of these waters create the most powerful galvanic battery that
—
is
found in the ocean.
Now,
it
may
be supposed
—
other things being equal
that the strength of this galvanic battery in the sea
depends in some measure upon the proportion of that the sea waters hold in solution, [lerature.
and
also
salts
upon tem-
§
27
THE PHYSICAL GEOGRAPHY OF THE
16
cHArrKR
If,
tliis
absence of better
in the
therefore,
SEA.
information,
suggestion be taken as a probability as to the origin
of these galvanic properties,
we may go
a step farther,
and draw the inference that the waters of the Gulf Stream, as they rush out in such volume and with such Chemical
vclocitv into the Atlantic, have not only chemical affini-
themselves, but, having more
ties peculiar to
higher
salts,
temperature, and a high velocity, they are not so per-
meable to water differing from them in
these respects,
all
and, consequently, the line of meeting between
them and
the other water of the ocean becomes marked.
This
the case with almost
Wliere
all
waters in rapid motion.
is
the Mississippi and Missouii rivers come together, there is
a similar reluctance on the part of their waters to mingle,
for the line of
meeting between them can be traced for
miles below the junction of the two rivers. §
29
The story
told
by the
indicates a higher point
sea water generally, Dr.Tho-
copper^
and the salometer confirms
colour''
it.
Dr.
Thomassy, a French savant, who has been extensively engaged in the manufactm-e of
txperir.
and the blue
of satm-ation with salts than
me
informs
tion,
salt
by
evapora-
solar
that on his passage to
the
United
States he tried the saltness of the water with a most delicate instrument
:
he found
contain 8^ per cent, of salt 4iV per cent.
per
the
with
West
and
in the
all
in the
Bay
;
Gulf Stream,
off Charleston,
Amazon and
the intermediate rivers, and
Indies,
had lent
of Biscay to
in the trade-wind region,
notwithstanding the
cent.,
sippi,
;
it
4
the Missis-
tlie
clouds of
their fresh water to dilute the
saltness of this basin. §
SO
Now, the question may be
asked, AYhat should
make
THE GULF the, waters of the
Mexican
STEEA:\I.
1
and Caribbean Sea
Giilf
7
Salter chapteb
_
than the waters of like temperature in those parts of the ocean through which the Gulf Stream flows
There are physical agents that are in is
to
and
make heavier,
employed by and
;
to be at
work
the waters in one part of the ocean Salter
and
another part lighter and
in
than the average of sea water.
structures
?
of the ocean, the tendency of which
parts
different
known
less
§
31
physica!
^^^""''^
salt
These agents are those matter for their
sea-shells in secreting solid
they are also heat* and radiation, evaporation
precipitation.
In the trade- wind regions at
sea,'
evaporation
is
gener-
ally in excess of precipitation, while in the extra-tropical
regions the reverse
down more water
is
the case
that
;
which
in
32
Evapora-
the clouds let
is,
there than the winds take
and these are the regions
§
up again
;
Stream
the Gulf
enters the Atlantic.
Along the shores of carefully made,
the
where experiments have been
India,
evaporation from
to three-fomi^hs of an inch daily.
Suppose
wind region of the Atlantic
amount
inch, that feet.
to
it
Now^ a
to only half
woidd give an annual evaporation of
is
taken up, the
33
§
34
in the trade-
In the process of evaporation from the
water only
§
the sea amounts
an
fifteen
sea, fresh
salts are left behind.
and as
layer of sea water fifteen feet deep,
broad as the trade-wind belts of the Atlantic, and reaching across the ocean, contains an immense amount of
The great equatorial current
(Plate VI.)
salts.
which sweeps
from the shores of Africa across the Atlantic into the Caribbean Sea
is
a sm-face current; and
* According to Dr. Marcet, sea water contracts 1
Plate VIII,
2
may down
it
not bear
to 28°.
THE PHYSICAL GEOGRAPHY OF THE
18
SEA.
CHAPTER into that sea a large portion of those waters that
the
satisfied Reason
for
jf gQ
saltness of
caiibbean Sea.
—
^j^j
trade-winds with
thirsty [^
probablv does ^ i
—have we
have
vapour?
saltless
not detected here
of an accent that does tend to make the the foot-prints ^ n waters of tlie Caribbean Sea Salter, and therefore heavier .
than the average of sea water at a given temperatui'e It ciple
upon which
this
reasoning depends
whether the annual evaporation
from
concerned,
is
the trade-wind
regions of the Atlantic be fifteeH, ten, or five
layer of water, whatever be
its
by the clouds they take
it
in the
and pour
not
all
same place whence
it
it
down
tropical regions of the earth
is
—and
is
in showers
—on
on the land more water
soil to
came.
is let
The
feed the springs,
rest
down than sinks down
and retm'n through
Suppose the excess of precipi-
tioa.
tation in these extra-tropical regions of the sea to
but twelve inches, or even to but two
added
two
But
upon the extra-
the rivers to the sea.
inches or
evapo-
is
poured back
Effects of
to
The
the land as well as in
taken up into the clouds again.
through the
feet.
thickness, that
rated from this part of the ocean,
the sea
?
immaterial, so far as the correctness of the prin-
is
inches, as the case
to the sea in those parts,
may
—
it
amount twelve
is
be, of fresh
water
and which therefore tends
to lessen the specific gi-avity of sea water there to that
extent,
and
to produce a double efiect,
reason that what
is
taken from one
for the
scale,
simple
by being put
into the other, doubles the difference. J
Now
35
that
we may form some idea as to left by the vapour that
ence which the salts
the influthe trade-
winds, north-east and south-east, take up from sea water, is
calculated to exert in creating currents, let us
make
a
—
THE GULF STREAM. partial calculation to sliow liow
solution before
in it
was yet
much
was taken
it
it
is,^
we
vapour held
salt this
—
embrace an area of at
and the yearly evapora-
The
will suppose, fifteen feet.
salt
contained in a mass of sea water coveiing to
is
chapter
The north-east
in the state of sea water.
least three million square miles;
that
9
up, and, of coiu'se, while
trade- wind regions of the Atlantic
tion from
1
supposed tion in tu^
regions."
the depth of fifteen feet an area of three million square miles in superficial extent, would be sufficient to cover
the British islands to the depth of fourteen
feet.
water supplies the trade-winds with vapom",
becomes
infer
and as
Salter,
aggregation
among
from the
fact,^
are reluctant to
it
becomes
its particles
it
mix with those of the
stated,
ocean.
;
or whether
whether
trade- wind § 36 it
be from
and in consequence of which the
waters of the Gulf Stream are
chamiel
we may
that the waters of the Gulf Stream
waters to remain on the surface, fact just
this
Salter the forces of
are increased, as
Whatever be the cause that enables these the
As
therefore
it
be from the fact that the expan-
zone
compensate for this increased saltness
;
sufficient
is
or whether
it
to
be
from the low temperature and high saturation of the submarine waters of the inter-tropical ocean be owing to
all
do
know
surf\ice,
that they go into the
surface cun-ent.
;
or whether
of these influences too'ether that these
waters are kept on the
On
suffice
it
to
we
Sea^ as
a
and through
it,
Caribbean
then- passage
to say,
they intermingle with the fresh waters that are emptied into
the sea from the Amazon, the Oronoco, and the
Mississippi,
and from the >
§33.
clouds,
"
§27.
tersfoma
held together in their cmTent
sion from the heat of the torrid
it
Tradewind wa-
and the 8
§34.
rivers of the
THE PHYSICAL GEOGRAPHY OF THE
20
is Mixture of wa-
fresh
An immense volume
round about.
CHAPTER coasts
supplied from these sources. •
i
i
SEA.
of fresh water
make
It tends to i
i
sca Water, that the trade-winds have been
the
•
i
playmg upon
ter.
and
warmer, and lighter
di'iving along, less briny,
the waters of these large inter-tropical streams are
This admixture of fresh water
than sea water.
;
for
warmer leaves
still
the Gulf Stream a brine stronger than that of the extratropical sea generally,
but not quite so strong as that
of
the trade- wind regions.^ It is
Effect of
the tradewinds,
assume that the trade- winds, by their
safe to
constant force, do assist to skim the Atlantic of the water
them with vapour, driving
that has supplied
Caribbean Sea,
whence, for causes unknown,
by the channel
of the Gulf
into the
it
escapes
it
Stream in preference
to
any
other.* §
In the present state of our knowledge
37
wonderful phenomenon
this
—
for the
of the most marvellous things in the ocean little
more than
operation which saitness of Baltic
coucemed
and
North
—we
is
one
can do
But we have two causes
conjecture.
we may
concerning
Gulf Stream
safely
in
assume are among those
One
in producing the Gulf Stream.
of these
.
.
in the increased saitness of its water alter the trade-
is
winds have been supplied with vapour from or
and the other
little;
salt
which
the' Baltic
The waters of the
it,
in the diminished
is
be it much quantum of
and the Northern Seas
Baltic are nearly fi-esh
to contain only about half as
much
;
contain.
they are said
salt as sea
water does
generally. 5
Now
38 *
The
here
we
have, on one side, the Caribbean Sea
fact is familiar to all concerned in the inanufacture of salt
poratiou, u at the first
show
of crystallization »
§29.
commeuees
by
solar eva-
at the surface.
THE GULF
21
STREAJNI.
and Gulf of Mexico, with their waters of brine other, the
gi-eat
two
Sea, the
latter
than brackish. f is
with waters
In one
heavy; in the other
ocean intervenes
maintain
on the
and
;
tliat
are but
is
—
1-
water
Between them the
light. is
chaptkr
more
little
set of these sea-basins the it
but water
;
level
its
;
Polar basin, the Baltic and the North
bound
to seek
and to
we unmask one
here, therefore,
one agent conceiT)ed
agents concerned
of the
What is it, it
causing the
— —we
the influence of this agent
is
and
is
in
to
what extent does
it
go
Gulf Stream,
that
is,
can not say
at least one of the agents concerned.
speculate as collecting
we may
great ;
stream.
only
Moreover,
as to all the agencies concerned in
have supplied the trade-
waters, that
these
how
in causing
winds with vapour, into the Caribbean Sea, and then in driving
them
across
sure, that the salt
the Atlantic
—
of this
we may be
which the trade-mnd vapour leaves
behind in the tropics has to be conveyed away from the trade-wind region, to be mixed up again in due proportion with the other
the Ai'ctic
water of the sea
Ocean included
the ofiices which, in the
assigned to
As
—
the Baltic Sea and
that these are some of
rmming ofl" through the To convey them away is doubtless one of
the waters at least which
Gulf Stream.
—and
we
see
economy of the
ocean, has been
it.
to the temperature of the Gulf Stream, there
is,
in Temper*-
a winter's day, off Hatteras, and even as high up as the
Grand Banks of Newfoundland
in
mid
ocean, a difference
t The Polar basin has a known water area of 3,000,000 squai-e miles, aud an unexplored area, including land and water, of 1,500,000 square miles. Whetlier the water in this basin be more or less salt than that of the inter-tropical seas, we know it is quite dififerent in temperature, and difference of temperature will beget currents quite as readily as difference in saltuess, for change in specifio gravity follows either.
;
THE PHYSICAL GEOGRAPHY OF THE
22 CHAPTER
between
its
and even
'
SEA.
waters and those of the ocean near by of 20°,
we know, expands by heat, and may more than com-
Water,
80°.
here the difference of temperature
pensate for the difference in saltness, and leave, therefore, the waters of the Gulf Stream lighter by reason of their
warmth. §
If
39
they be
they should therefore occupy a
lighter,
higher level than those through which they flow.
suming the depth Expansion
off
As-
Hatteras to be one hundred and
fourteen fathoms, and allowing the usual rates of expansion for sea water, figures
show that the middle
or axis of
the Gulf Stream there should be nearly two feet higher
Hence the
than the contiguous waters of the Atlantic.
surface of the stream should present a double inclined
Form.
plane, from
which the water would be running do\vn on
either side as from the roof of a house.
at the top, the
As
this runs off
same weight of colder water runs
in at the
bottom, and so raises up the cold water bed of the Gulf Stream, and causes as
it
goes north.
it
to
become shallower and shallower
That the Gulf Stream
shaped, causing the waters on either side from the middle,
its
is
therefore roof-
sm-face to flow off to
we have
not only circum-
stantial evidence to show, but observations to prove. §
40
Surface
Navigators, while drifting along with the Gulf Stream,
have lowcred a boat to try the surface current.
current.
,
such
cases,
the
to the west, as it
,
boat would
.
^
di-ift
happened to be on one
side or the other
of the axis of the stream, while the vessel herself drift
In
.
either to the east or
along with the stream in the direction of
its
would course
thus showing the existence of a shallow roof-current from the middle toward either edge, which would carry the
—
THE GULF
23
STREA^I.
boat along, but which, being superfcial, does not extend chaptee
deep enough to affect the drift of the
That such
the case^
is
by the circum-
also indicated
is
—
vessel. §
41
stance that the sea-weed and drift-wood which are found in
such
along the outer edge" of the
quantities
large
Gulf Stream, are
even
never,
easterly winds, found along
simple reason
to
that to
over from
pass
up an ^
di'ift
cross the
that
side
the prevalence of
-with
inner edge
its
to
for the
Gulf Stream, and to
it
would have
they
this,
inclined ])lane, as
—and
were
'J
that
;
is,
they
,
would have
stem
to
this roof-current until
We
the middle of the stream.
they reached
Erection of drift-
wood,
&c
rarely hear of planks, or
wrecks, or of any floating substance winch
is
cast into
the sea on the other side of the Gulf Stream being found
along the coast of the United States.
and seeds from the West India
Drift-wood, trees,
islands,
are said to have
been cast up on the shores of Euro})e, but never, that I ever heard, on the Atlantic shores of this country.
We
now
are treating
The question
to
which
Gulf Stream slough
upon
floating
One cmTent
same
I ask attention
off
weed, drift-wood, and
of the effects of physical causes.
and
all
but there
effect
;
its
Why
does the
outer edge, sea-
causes of the direction of
other solid bodies that are found
it?
cause has been ;
upon
cast
is.
is
shown
anotlier
and because
it is
not, in a treatise of this kind,
never so
slight.
upon the
drift
I
allude
to be
in its roof-shaped
which tends
to
a physical agent,
it
should
be overlooked, be
its
action
now
§
42
produce the
to the effects produced
matter of the stream by the diurnal rota-
tion of the earth.
Take, for illustration, a railroad that runs nortli and 1
§ 39.
«
§ 13.
§ .^3
— THE PHYSICAL GEOGRAPHY OF THE
24;
CHAPTER south.
It
are going north on
run
south, their tendency
the track luastra-
i. e.,
is
the cars
a road, their tendency
sncli
on the east side
off
when
well kno^^^l to engineers that
is
SEA.
but when the train
;
to
ran
off
is
is
to
going
on the west side of
always on the right-hand side in our
Whether the road be one mile or one hun-
hemisphere.
dred miles in length, the effect of diurnal rotation same, and the tendency to run
off,
parallel at a stated rate of speed,
the road be long or
sliort,
you
as is
the
is
cross a given
the same
;
whether
the tendency to fly off the
track being in proportion to the speed of the trains, and
not at §
44
Diurnal
proportion to the length of the road.
all in
Now,
and velocity being taken into the
vis inertice
accouut, the tcudeucy to obey the force of this diurnal
rotation.
rotation, gi*eat in
and
to trend to the right, is proportionably as
the case of a patch of sea- weed as
the Gulf Stream, as
it is
it drifts
along
in the case of the train of cars
as they speed to the north along the iron track of the
Hudson Kiver
railway, or
The
north and south.
them from flying
any other railway that
rails restrain
but there are no
off*;-
lies
the cars and prevent rails to restrain
the sea-weed, and nothing to prevent the drift-matter of
the Gulf Stream from going off in obedience force.
The
moving
freely in
to this
slightest impulse tending to turn aside bodies
water
is
immediately
and implicitly
felt
obeyed. §
45
It
is
in
consequence
down
drift-wood coming
of this
is
so very apt
to be cast
upon the west or right bank.
reverse of
what obtains upon the Gulf Stream,
flows to the north
;
it
therefore slouo-]is
§43,
that
diurnal rotation
the ]\Iississippi
off''
This
is
the
for it
to the east.
—
THE GULF The
of diurnal
effect
STREA:M.
upon the winds and
rotation
upon the cuiTents of the sea
is
admitted by
trade- winds derive their easting from
extend to
fore,
all
25
it
—
all
—
chapter
—
the
Its effects
must, there-
it
the matter which these currents bear
on the Currents!
with them, to the largest iceberg as well as to the merest of
spii-e
that floats upon the waters, or the minut-
gi-ass
est organism that the most
detect
among
eflect
of
powerful
microscope
the impalpable particles of sea-dust.
diurnal rotation
upon
drift will
can This
be frequently
alluded to in the pages of this work.
In
its
course to the north, the Gulf Stream gradually
trends
more and more
off the
Banks of Newfoundland, where
nearly due
from
its
its coui'se
will prove,
frigid cun-ent already
It
spoken of,^with
is
its
becomes
to take this
they are
here that the icebergs
fi'om
met and melted by the warm waters Of com'se the loads of earth, stones, and gravel brought down upon them are here deposited. Captain Scoresby, far away in the north, counted five hunthe of
north,
tlie
are
Gulf
di'ed icebergs setting
out from the same vicinity upon this
Many
cold current for the south. earth, cess
shoals,
This pro-
from the north for these
and of snowing down upon them the infusoria
and the corpses of so
of them, loaded with
have been seen aground on the Banks.
of transferring deposits
" living
abundantly in the
and sloughed between
it
off in
warm
myriads
creatures" that are spawned
waters of the Gulf Stream, for burial
where the
and the great Polar current' takes '
§ 11.
"
§
U.
45
Banks
of
Newfoundf
it
think, that
I
§
arrives
.
proper course, and cause
certainly not the cause.
effect,
it
has been thought,
it
.
it
Examination
turn.
an
These banks,
east.
.
deflect
to the eastward, until
conflict
place,
land.
THE PHYSICAL GEOGRAPHY OF THE
26 CHAPTER
—
everlastingly going
is
These agencies, with time,
on.
seem altogether adequate
SEA.
the formation of extensive
to
bars or banks.
The deep
Their
made by
sea soundings that have been
ves-
fjnrjition.
of the navy tend to confirm this \de"w as to the
sels
The
formation of these Banks,
bottom of the Atlantic
Nowhere
Banks.
the south
of
these
in the open sea has the water been
found to deepen so suddenly as
bottom of the sea
north, the
greatest contrast in the
just to
is
Banks,
after passing these
precipitous descent for
its
Coming from the
here.
is
sheh^ng
but suddenly,
;
depth increases by almost a
many thousand
thus indicat-
feet,
ing that the debris which forms the Grand Banks conies
from the north. §
From
47
the Straits of Bemini the course of the Gulf
Stream (Plate VI.) describes
(as far as it
can be traced
over toward the British Islands which are in the midst of
its
waters) the arc of a gi^eat circle as neaidy as
may
Such a
very
as the Gulf
Course of the Gulf
be.
stream,
nearly the course that a cannon
from these If
it
coui'se
straits to those islands,
Stream takes could
ball,
would
it
is
be shot
describe.
were possible to see Ireland from Bemini, and to
get a cannon that would reach that
far,
the person stand-
ing on Bemini and taking aim, intending to shoot at Ireland as a target, would, direct,
48
Piumai
But there volve ou
its
axis
;
and
rotation since
,
cquator than Ireland diurnal
is,
the
rotation^ faster than
'
for difference
rest,
sight
of motion
target.
diurnal
is
rotation affects its
the earth were at
and make no allowance
between marksman and §
if
Plat€ XI.
;
earth
the
Bemini
nearer to the
is ^
does re-
,
.
gun would be moving the target, »
§ 16.
and
m .
therefoi-e
;
THE GULF
27
STREA:\r.
marksman, taking aim point blank at
the
would
He would
miss.
had shot south other words, ball
—
that
is,
to the rigld^ of his
and the
—
In
by the
this difference in the rate
trajectile force
would cause the
to the east,
mark.
actually described
would be the resultant of
of rotation
target, cHAriEB
on examination, that he
find,
the path
that
his
the former, impelling
;
ball to describe a great circle,
but one with too much obliquity to pass through the tar-
Like a ray of light from the
get.
the ball would
stars,
be affected by abeiTation. It
the case of the passenger in the
is
railroad
car
§
49
throwing an apple, as the train sweeps by, to a boy standing by the wayside.
throw straight at the boy, he
If he
illustration.
will miss, cars, will
for the apple,
partaking of the motion of the
go ahead of the boy, and for the very reason
that the shot will pass in advance of the target, for both
the
marksman and
the passenger are going faster than
the object at which they aim.
Hence we may assume tendency of
all
it
currents in
as a law, that the natural
the
sea,
the
like
natm-al
§
50
Natural teiid€iicv
tendency of
all projectiles
through the
air,
is
to describe
their cm-ves of flight in the planes of great circles.
natural tendency of
when put
in motion,
The is
to
go from point to point by the shortest distance, and
it
all
matter,
requires force to overcome this tendency.
and
electricity,
running water, and
all
ponderable or imponderable, seek,
obey
this law.
course,
and so
Electricity
may
may
Light, heat,
substances, whether
when
in motion, to
be turned aside from
its
the cannon ball or running water
but remove every obstruction, and leave the current or the shot free to continue on in the direction of the '
§i3.
first
ofcunecta curves.
THE PHYSICAL GEOGRAPHY OF THE
28
of the Gulf Stream are
must have room, and gains
warmer waters
right.
/--,
for § 56
change of
for this
In winter, the volume of cold water on
the American, or creased.
The banks
obvious.
water.
cold
The reason
in turn,
motion
is
press
made by the United
Survey indicate that there are in the threads of warmer, separated
by
them back,
preserved.
States Coast
Gulf
Stream
§2.
57
warm and
streaks of cooler water, cow water
See Plate YL, in which these are shown; they are marked '
§
streaks of
THE PHYSICAL GEOGRAPHY OF THE
82 CHAPTER x, y,
——
A may
Figure
z.
SEA.
be taken to represent a thermo-
metrical cross section of the stream opposite the Capes of Virginia, for instance; the top of the curve representing
the thermometer in the threads of the
warmer water, and
the depressions the height of the same instrument in the streaks of cooler water between; thus exhibiting, as one sails
from America across the Gulf Stream, a remarkable
series of thermometrical elevations
surface temperature of this §
These streaks,
58 as
it
from
issues
x, y, z,
and
to be an incident of the process Suppoaed
Stream gradually grow
of the
it
it
to the
have thought them by which the waters
I
cool.
calm over this stream, and that top of
in the
in the sea.
are not found in the Gulf Stream
fountain,
its
and depressions
mighty river
all
Suppose a perfect the water on the
depth of ten feet were suddenly, as
runs along in a winter's day, to be stricken by the
wand
of
some magician, and reduced from the tempera-
ture of 75° to that of 32°, the water below the depth of
ten feet remaining at 7-5° as before. cold
and heavy water sink
floor or field of ice
loaded to sinking? rise field,
to the rising
middle
?
up
this
Like a great water-tight
?
over the edges,
I think not
warm water would
would
as broad as the Gulf Stream, and And how would the warm water
By running
top?
How
;
rise
that the cold would go
out under this floor or
and flowing back to the
on the contrary,
I
up here and there in
down
suppose the streaks,
in streaks or seams.
and
The
would be not unlike what we see going on in a fountain which is fed by one or more bubbling springs We can see the warm water rising up in a from below. process
column from the
orifice
below, and in winter the water
— GULF
TTIE
on the top
grows cool and then
first
S3
STREA]VI.
Now, ima-
sinks.
cHAriER
L
giue the fountain to be a long and narrow stream, and this orifice to be a fissure runnincr along at the
the middle of
it,
can well imagine
up
rising
the
all
and feeding
it
warm
with
bottom in
We
water.
there would be a seam of water
tliat
way
middle of the stream, and
in the
that a delicate thermometer would, in cold weather, show
a marked difference of temperature between the water as
up
it rises
in this seam,
and that going down on either
Now,
side after it has been cooled.
if
ginary stream broader, and place at a other fissure parallel with the
warm
we make our imalittle
and
first,
distance an-
also supplying
water, there would be between the two a streak of
cooler water descending after having parted
with a cer-
and thus we would
tain degree of heat at the surface,
have repeated the ribbons of cold and
warm water which
the Coast Survey has found in the Gulf Stream.
The hottest water lightest
;
as
it rises
poration and exposure,
by
Gulf Stream
in the
to the top,
it
when
the surface
fresh supplies of hot water
Winter
is
cooled both
is
also
the
by
eva-
Stream
day, off
the waters at
from below. the
surface
Cape Hatteras may be at
depth of five hundred fathoms
Thus, in a
—
of
80°,
Gulf
the
and at the
—
three thousand feet
as
actual observations show, the thermometer will stand at
Following the stream thence off the Capes of Vir-
5 7**. ginia,
one hundred and twenty miles,
the water-thermometer having been
the
way
—
that
it
surface, while all
now
it
will be
is
cooler.
found
carefully noted all
stands a degree or
below
59
replenished
is
,
s
§
two
less at
the
In other words, the
stratum of water at 57", which was three thousand feet
TemperatnreofGui/ stream.
34 caAPTER
THE PHYSICAL GEOGRAPHY OF THE
below the surface
off Hatteras,
has,
SEA.
in a course of one
hundred and twenty or one hundred and thirty miles
in
a horizontal direction, ascended, vertically, six hundred feet
;
that
is,
this
stratum has run up
hill Avith
an ascent
of five or six feet to the mile. §
As a
60
rule, the hottest
or near the surface is
sent down,
water of the Gulf Stream
at
and as the deep-sea thermometer
;
shows that these waters, though
it
is
still
far
warmer than the water on either side at corresponding depths, gradually become less and less warm until the bottom of the current lieve that the
warm
where permitted, bottom of the
is
lu
effect
There
sea.
climate of
Stream
Europe,
otherwise
is
in regions
to it
is
reason to be-
everywhere a cushion of
them and the
This arrangement
One
ingly beautiful
is
the oceanic economy, to touch the
in
cool water between earth's crust.
There
reached.
waters of the Gulf Stream are no-
is
solid
parts
suggestive,
of the
and
strik-
of the benign offices of the Gulf
convey heat from the Gulf of Mexico, where
would become
beyond the
excessive,
and
Atlantic, for the
to dispense
it
amelioration of
the climates of the British Islands and of aU Western
Europe,
Now,
tors of heat,
cold water
and
if
is
one of the best non-conduc-
warm water
the
of the Gulf Stream
was sent across the Atlantic in contact with the crust of the earth
—
heat
with a it
—
comparatively a good conductor of
instead of being sent across, as cool,
solid
it
is,
in contact
non-conducting cushion of cool water to fend
from the bottom,
all its
heat would be lost in the
fii'st
part of the way, and the soft climates of both France
and England would be
as tliat of Labrador, severe in the
extreme, and ice-bound.
•
INFLUENCE OF THE GULF STREAJM UPON CLL^UTES.
CHAPTER
85
II.
INFLUENCE OF THE GULF STREA3I UPON CLDtATES. How
—
the Climate of England
Atlantic, 65.
is regulated by it, § 61. Isothermal Lines of the —Deep-sea Temperatures under the Gulf Stream, 68. Currents
—
— Sea-nettles, 73. — Climates of the Sea, 75. — — Influence of the Gulf Stream upon the Meteorology of the of the Sea, — Furious Storms, 80. — Dampness of the English Climate due to the Ocean, — Influence upon Storms, — Wreck of the Steamer San Gulf Stream, Francisco, — Influence of the Gulf Stream upon Commerce and Navigation, 96. — Used for finding Longitude, 103. — Commerce in 1769, 106. indicated by the Fish, 70.
Offices
76.
78.
83.
85.
Its
88.
Modern
ingenuity has suggested a beautiful mode of warming bouses in winter. It is done by means of hot water. The furnace and the calib'on are sometimes •
chapteh
—
§ fil Principle
placed at a distance from the apartments to be warmed,
of heating
apparatus.
It
is
so at the Observatory.
to conduct
tlie
In
used
this case, pipes are
heated water from the caldron under the
superintendent's dwelling over into one of the basement
rooms of the Observatory, a distance of one hundred
feet.
These pipes are then flared out so as to present a large cooling surface again, through
of
its
own
turning
all
;
after
which they are united into one
which the water, being now
accord to the caldron.
Thus
cooled, returns
cool water
is
re-
the time and flowing in at the bottom of the
caldron, while hot water
is
continually flowing out at the
top.
The
ventilation of the Observatory
is
so arranged that
the circulation of the atmosphere through this pai-ts
basement room, where the pipes of the building
;
and
it
are,
is
led from
to all other
in the process of this circulation.
THE PHYSICAL GEOGRAPHY OF THE
36
SEA.
warmth conveyed by the water to the basement is taken thence by the air and distributed over all the rooms. Now, to compare small things with great, we
CHAPTER the
—
'-
warm
have, in the
waters which are confined in the Gulf
of Mexico, just such a heating apparatus for Great Britain,
the North Atlantic, and Western Europe. §
The furnace
62
is
the torrid zone
siTtioarity
Caribbean Sea are the
stream,
the conductiug pipe.
From
—
chamber
in
which
the
;
this
pipe
that the
is
—
the
flared out so as
is
Here the
arranged by nature
is
Banks of New-
the basement
is
to present a large cooling surface. of the atmosphere
Gulf Stream
the Grand
foundland to the shores of Europe hot-air
the Mexican Gulf and
;
caldrons
;
circulation
and
such,
it is
warmth thus conveyed into this warm-air chamis taken up by the genial west winds,
ber of mid-ocean
and dispensed, in the most benign manner, throughout Great Britain and the west of Europe.
The maximum temperature
§ 63
chamber of the Observatory
mum
is
of the water-heated air-
about 90°.
its
is 86**,
or about 9"
latitude.
Increasing
temperature of the Gulf Stream
above the ocean temperature due the latitude
1 0°, it losas
The maxi-
but 2° of temperature
;
and, after
having run three thousand miles toward the north, preserves, even in winter,
it still
With
the heat of summer.
this temperature, it crosses the
40th degree of north
lati-
tude,
and
itself
out for thousands of square leagues over the cold
there, overflowing its liquid banks, it spreads
waters aroimd, and covers the ocean with a mantle of Kffccf on
warmth that
climate,
rigours of wiutcr.
sei-ves
so
much
]\Io\ang
j)ensing its genial influences
to mitigate in
now more more
Europe the
slowly, but dis-
freely, it finally
meets
INFLUENCE OF THE GULF STREAil UPON CLIMATES. 37 the
By
British Islands.
these
it
is
divided/ one part coaptkr
going into the polar basin of Spitzbergen, of Biscay,
mense volume of heated water cannot beyond the
this it is
seas a mild
which
so
other
but each with a warmth
considerably above the ocean temperature.
it
the
Its CffGCt
Bay
entering the
much
Such an
fail to
ira-
on the theBritisii
carry with
and moist atmosphere.
And
softens climate there.
We know not, except approximately in one or two places,
§ (34
what the depth or the under temperature of the Gulf Stream may be; but assuming the temperature and velocity at the depth of two hundred fathoms
and taking the well-known
be those of the surface,
to
difference
caicuia-
between the capacity
of air and of water for specific heat as the argument,
a simple calculation will show that the quantity of heat dischargfed over the Atlantic
Stream
in a winter's day,
from the waters of the Gulf
would be
whole column of atmosphere that
sufficient to raise the
rests
upon France and
the British Islands from the freezing point to
summer
heat.
Every west wind that blows to
to
temper there
tlie
carries
Emerald
with
it
on
its west
a portion of this heat
northern winds of winter.
influence of this stream "
crosses the stream
winds
way
Europe, and
It
is
affected
the
upon climate that makes Erin the
Isle of the Sea,"
and that clothes the shores of
Albion in evergreen robes; while in the same latitude, on this side, the coasts of
of
ice.
yet
bound
in fetters Mr. Red-
paper on
was
who
fast
Newfound-
states that in
land,
Labrador are
In a valuable paper on currents,* Mr. Redfield
1831 the harbour
of St. John's,
closed with ice as late as the
month
of June;
ever heard of the port of Liverpool, on the other *
American Journal of Science, 1
Plate IX.
vol. xiv., p. 293.
38
THE PHYSICAL GEOGRAPHY OF THE
CHAPTER side, II.
though 2° farther north, being closed with
.
65
even
ice
.
in the §
SEA.
dead of ^vinte^
?
The Thermal Chart
(Plate IV.)
50°
shows
isothemiai lilies of the
thermal Hnes of
Atlantic,
parallel of 40** near the coasts of the off in
60",
&c.,
this.
starting ^
off
United
The
iso-
from the States, run
a north-eastwardly direction, showing the same
oceanic temperature on the European side of the Atlantic in latitude
55" or
in latitude
^O**.
60**,
we have on
that
the western side
Scott, in one of his beautiful novels,
tells
us that the ponds in the Orkneys (latitude near
are
not frozen in winter.
soft climate to this
The people there owe
grand heating apparatus,
from the West Indies
is
60**)
their
for diiftwood
occasionally cast ashore there
by
the Gulf Stream. §
66
Beneficial
Nor do
the beneficial influences of this stream upon
climate end here.
influence
The West Indian Ai'chipelago
compassed on one side by
on South
the other
climate,
.
.
of the
by the
en-
is
.
.
its
chain of islands, and on
Cordilleras of the Andes, contracting
with the Isthmus of Darien, and stretching themselves out over the plains of Central America and Mexico.
ginning on the summit of this range,
we
of perpetual snow, and descend
into the tierra
first
Be-
leave the regions tetiv-
plada, and then into the tierra caliente, or burning land.
Descending
still
surface of the
beautifid
lower,
Mexican
we
reach both the level and the
seas,
where, were
not for this
it
and benign system of aqueous
cu'culation, the
peculiar features of the suiTOunding country assm-e us
should have the hottest, climate in
the world
if
As
not
the
the waters
caldrons become heated, they are borne
Stream, and
ai-e
replaced
by
most
we
pestilential
these two by the Gulf
in
ofi*
cooler cm-rents through thft
-
:
INFLUENCE OF THE GULF STREAM UPON CLIMATES. Caribbean Sea
the surface water, as
;
3° or 4°, and that in depth
Taking only
escapes from the Gulf.
liere,
being
when
cuaj-tes
—
it
this difference in
temperature as an index of the heat accumulated
Eui'face
a simple calculation will show that the quantity
there,
of heat daily carried off
by the Gulf Stream from those
and discharged over
regions,
tlie
Atlantic,
is
sufficient to
mountains of iron from zero to the melting point,
raise
and
enters
it
40°* cooler than
39
keep in flow from them a molten stream of metal
to
greater in volume than the waters daily discharged from
Who,
the Mississippi River,
therefore can calculate the
benign influence of this wonderful cmrent upon the climate of the South
the
mind
nature fill
?
up
led from nature
is
and what mind
;
In the pursuit of this subject,
with profitable emotions
ing alone, of
emblem
of
its
Yea,
deep.
study of this subject not
Unchanged and unchang-
?
created things, the ocean
all
"
everlasting Creator.
the waves of the sea," and "
to the great Architect of
will the
He
is
He
is
the great
treadeth upon
seen in the wonders of the
calleth for its waters,
and pom-eth them
out upon the face of the earth."
In obedience to this planet preserves it
heat and
regions
land
;
;
its
warmth
the aqueous portion of our
call,
beautiful system of circulation.
are dispensed to the extra-tropical
clouds and rain are sent to
and by
it
By
refresh
the dry
cooling streams are brought from Polar
Seas to temper the heat of the torrid zone.
At
the
depth of two hundi-ed and forty fathoms, the temperature * Temperature of the Caribbean Sea (from the journals of Mr. Dunsterville) Surface temperature 83°, September 84°, July 83°-^S6^°, Mosquito Coast. :
Temperature
;
;
depth: 48°, 240 fathoms; 43°, 386 fathoms; 42°, 450 fathoms; 43°, 500 fathoms. in
«
gy
THE PHYSICAL GEOGRAPHY OF THE
40
SEA.
tlie Caribbean Sea has been found as low as 48°, while that of the surface was 85".
of the cm-rents setting into II.
Tempera-
with three hundi-ed and eighty-six fatlioms
ture of
Another
currents in the
gave 43° below against 83° at the surface.
Caribbean Sea.
The
hurri-
of those regions agitate the sea to great depths
canes
that of deep,
cast
1780
and
them
cast
;
up from the bottom seven fathoms
tore rocks
They
ashore.
therefore cannot
fail
to bring to the surface portions of the cooler water below.
At
§68 At the bottom of Gulf Stream.
the very bottom of the Gulf Stream,
was
face temperature
80°, the deep-sea
when
its sur-
thermometer of
the Coast Sm'vey has recorded a temperature as low as
35° Fahrenheit.
These cold waters doubtless come
§69 Within the
to replace the
warm water
down
fi'om the north
sent through the Gulf Stream
Arctic Circle.
to
moderate the cold of Spitzbergen
;
for within
the
Arctic Circle the temperature at corresponding depths off
the shores of that island
is
said to be only one degree
colder than in the Caribbean Sea, while on the coasts of Labrador and Polar
Labrador, and in the Polar Seas, the temperature of the
Seas.
water beneath the
De Haven Off coast
water
ice.
ice
was invariably found by Lieutenant
at 28°, or 4°
below the melting point of
Captain Scoresby
relates, that
fresh-
on the coast
of Greenland.
of Greenland, in latitude 72°, the temperature of the air
was 42°; of the water, 84°; and 29° surface current setting to the south,
centres, perhaps,
there found a
and bearing with
it
with vast numbers of icebergs,
this extremely cold water,
whose
at the depth of
He
one hundi-ed and eighteen fathoms.
were
far
below
zero.
It
would
be curious to ascertain the routes of these under currents on their
way
tended to
to the tropical regions,
cool.
One has
Ijeen
»
§23.
which they are
in-
found at the equator two
INFLUENCE OF THE GULF STREAil UPON CLIMATES.
41
hundred miles broad, and 23" colder than the surface Unless the land or shoals intervene,
water.
comes down in a
spiral
it
chapteh
—
no doubt
'-
curve, approaching in its course
the great circle route.
Perhaps the best indication as to these cold currents
may
be derived from the
first
pointed out the existence of the Gulf Stream by
avoiding
its
warm
fish
The whales
of the sea.
Along our own
waters.
§
70
currents byfisii.
coasts, all
those delicate animals and marine productions which delight in
warmer waters
are wanting; thus indicating,
by
their absence, the cold current from the north now known to exist there.
In the genial warmth of the sea about
the Bermudas on one hand, and Africa on the other, find in wreat
abundance
those delicate shell-fish
and
formations which are altogether wanting in the same
tudes alono" the shores
;
for there the
cold current almost reaches the line before the
of coral
A core
is
fii'st
sprig
found to grow.
few years ago, great numbers of bonita and
—
lati-
The same
of South Carolina.
obtains in the west coast of South America
we
coral
tropical fish
—
alber-
§
71
§
72
following the Gulf Stream, entered
the Encjlish Channel, and alarmed the fishermen of Corn-
wall and Devonshire
among It
by the havoc which they created
the pilchards there.
may
well be questioned
towns do not owe
if
our Atlantic
cities
and
their excellent fish-markets, as well as
our watering-places their refreshing sea-bathing in summer, to this stream of cold water. the Mediterranean ture of the
same
most part, very
is
4° or
latitude,
5°
above the ocean tempera-
and the
indifferent.
The temperature of
On
fish there are, for
the
the other hand, the teni-
THE PHYSICAL GEOGRAPHY OF THE
42
SEA.
below that
CHAPTER perature along our coast is several degrees
—
'-
of
the ocean, and from Maine to Florida our tables are sup-
most excellent of
plied with the so
much esteemed warm
flavour,
and
with other coast,
is
fish
;
coral
when taken
:
a
sheep's-head,
Carolinas,
banks of the Bahamas,
The same
held in no esteem.
they have
esteemed
and the
in Virginia
taken on the
The
fish.
in the cold
delicious
the case
water of that
and are highly
flavour,
but when taken in the
is
when
loses its
warm water on
the
other edge of the Gulf Stream, thouiih but a few miles unfit for the table.
The
temperature of the water at the Balize reaches 90".
The
distant, their flesh is soft, Effects of
and
tempe4'a-
ture on
taken there are not to be compared with those of the
fish
fiih.
same
her choicest current
Orleans, there-
to the cool waters on the Florida coasts for
fore, resorts
A
New
latitude in this cold stream.
The same
fish.
of
shores of Chili, Peru,
the
south sweeps the
and Columbia, and reaches the
pagos Islands under the distance, the
the case in the Pacific
is
cold water^ from
Throughout
line.
this
Galli-
whole
world does not afford a more abundant or
excellent supply of
Yet out
fish.
in the Pacific, at the
Society Islands, where coral abounds, and the water preserves a higher temperature, the
fish,
though they vie in
gorgeousness of colouring with the birds, and plants, and insects of the tropics, are held in
of food. still
I
have known
sailors,
to prefer their salt beef
taken there. this subject
The few seem
facts
no esteem as an
article
even after long voyages,
and pork
to a
mess of
fish
which we have bearing upon
to suggest it as a point of the inquiry
to be made, wliether the habitat of certain fish does not
indicate
tlie
temperature of the water, and whether these »
§455.
INFLUENCE OF THE GULF STREAM UPON CLIMATES,
43
and warm currents of the ocean do not constitute the
cold
great highways through
which migratory
from one region to another.
much
"VVliy
ohapteb
—
'-
fishes travel
should not
fish
be as
the creatures of climate as plants, or as birds, and
other animals of land, sea, and air
we know
Indeed,
?
that some kinds of fish are found only in certain climates.
In other words, they live where the temperatm-e of the
water ranges between certain degrees. Navigators have often met
young
They are known
Stream.
food for the whale
caused
with vast numbers
much
;
of
with the Gulf
sea-nettles {medusoi) drifting along
§
73
sea-nettiea
the principal
to constitute
but whither bound by this route has
speculation, for
is
it
well
known that the warm waters
habits of the right whale are averse to the
An
of this stream.
the Gulf Stream on the coast
of Florida, he feU in with such a " school of nettles as
had never before been heard
covered with them for
;
many
leagues.
sea
sea-
was
likened them,
but they were so thick as to completely cover
He was bound
the sea.
to England,
days in sailing through them. ward, on his return, he
in passing
them
again.
in with the
fell
He
and was
was
same school
off
three or four days
recognized them as the same,
he had never before seen any like them
occasions he
five or six Anecdott
In about sixty days after-
the Western Islands, and hei^e he
for
The
of,"
He
young
on the water, to acorns floating on a
in appearance
stream
me
informs
intelligent sea-captain
that, several years ago, in
;
and on both
frequently hauled up bucketfuls
and ex-
amined them.
Now, for
the Western Islands
whales
:
and
at first there
is tlie is
great place of resort
somethincr curious to ub
§
74
THE PHYSICAL GEOGRAPHY OF THE
44
CHAPTER in the idea that
—
'~
the Gulf of Mexico
SEA.
is
the harvest-field,
and the Gulf Stream the gleaner which
collects the fruit-
age planted there, and conveys
hungry whale at
to the is it
thousands of miles off
it
But how
sea.
perfectly in unison
with the kind and providential care of that great
and good Being which feeds the young ravens when they cry, §
75
ciimatesot the sea.
and caters
The
sparrow
for the
sea has
chauge with the latitude
botli
!
They
climates as well as the land.
its
but one varies with the
;
elevation above, the other with the depression below the
The
sea level. tion
;
climates in each are regulated
but the regulators
are,
by
circula-
on the one hand, winds
on
;
the other, currents. §
76
The inhabitants
much
of the ocean are as
of climate as are those of the dry land
Almighty hand which decked the sparrow,
fashioned also the
lily
pearl
the creatures
same
for the
;
and
cares for the
and feeds the great
whale, and adapted each to the physical conditions by
which
his providence has
land or the Offices of
sea,
sea,
therefore,
we may
duties to perform
and
so, too, its
takes to stvidy
exquisite
;
so,
its
in
has
;
infer,
economy. its
have
consequently, he
phenomena must
He must
of
offices
its
it
The and
currents,
who under-
cease to regard
look upon
tlie
his creatures,
all
his
safely infer,
may we
inhabitants
a waste of waters. that
and agents
Whether
it.
inhabitants are
the
subjects of his laws,
surrounded
it
as
as a part of
machinery by which the harmonies of
nature are preserved, and then he will begin to perceive the developments of order tliese
make
it
contemplation.
and the evidences of design
;
a most beautiful and interesting subject for
—
^
;;
INFLUENCE OF THE GULF STREAM! UPON CLIMATES.
45
To one who has never studied the mechanism watch,
main-spring or the balance-wheel
its
He may
metal
piece of
it
wondered
keeps, or the
in idle
machinery which
time
amazement is
of a chapter
it
plays,
its
hands, and
he
may have
^
as to the character of the
Take
concealed within.
and show him each part
—
a mere
have looked at the face of the
watch, and, while he admires the motion of the time
is
it
to pieces,
he will recognize
separately,
neither design, nor adaptation, nor relation between
them
but put them together, set them to work, point out the offices of
each spring, wheel, and cog, explain their move-
ments, and then show him the result; that
it is all
now he
ber of parts, their diverse forms and various the agents concerned, the whole piece
He now
the expression of one idea.
when
perceives
one design; that, notwithstanding the num-
•
is
offices,
of one thought,
rightly concludes that
/•I'll
•
1
the main-spring was fashioned and tempered,
relation to all the other parts
and
•
its
must have been considered cut and regulated
that the cogs on this wheel are
adapted
—
to the rachets
on
that, &c.
clusion will be, that such a piece of
have been produced by chance; parts
is
such as to show
it
;
and
his final con-
mechanism could not
for the adaptation of the
to be according to design,
obedient to the will of one intelligence.
So, too,
and
when
one looks out upon the face of this beautiful world, he
may admire
its
lovely scenery, but his admiration can
never grow into adoration unless he will take the trouble to look behind
and study,
in
some
of its details at least,
by which such beautiTo him who does this,
the exquisite system of machinery ful results are
brought about.
the sea, with
physical geography, becomes as the main-
its
Reflec-
l'on&
— 46
THE PHYSICAL GEOGRAPHY OF THE
CHAPTER spring of a salts,
and
watch;
and
its
cuiTents,
and
its
with their adaptations, as balance-
its inliabitants,
wheels, cogs
and
its watei-s,
SEA.
pinions,
and
Thus he perceives
jewels.
that they, too, are according to design; that they are the
expression of
One Thought, a unity with harmonies which and One Intelligence alone, could utter.
One
Intelligence,
A.nd
when he has
arrived at this point, then he feels that
the study of the sea, in It elevates the
blime.
Gulf Stream
now no
is
its
physical aspect,
truly su-
is
mind and ennobles the man.
by such an one merely
The
longer, therefore, to be regarded
as an
immense current of warm
water running across the ocean, but as a balance-wheel a part of that grand machinery by which air and water are adapted to each other, and is
by which
adapted to the well-being of
flora
which decks, and the
its
this earth itself
inhabitants
fauna which
—
of the
enlivens
its
surface. §
Let us
78
Influence of the Gulf
stieam on the meteoroiogyof
now
consider the influence of the Gulf Stream
upon the meteorology of the ocean. To use a saiior expression, the Gulf Stream "
1
1
,
wcather breeder
most clurious gales •
i
fogs of
gation
,,
c
t
•
^
the sjreat
•
^
wind sweep along vnih
oi
The
•
it;
and the
Newfoundland, which so much endanger naviin winter,
owe their existence to the of immense volumes of warm
doubtless
presence, in that cold sea,
water brought by the Gulf Stream. found the air on each side of while that of
damp
is
«
of the North Atlantic Ocean.
air
its
it
waters was 80*
Sir Philip .Brooke
at the freezing point, "
The heavy, warm,
over the current produced great irregularities
in his chronometers."
into such a region
The excess of heat
daily brouglit
by the waters of the Gulf Stream
INFLUENCE OF THE GFLF would,
make
STREA:^!
UPON CLDIATES.
suddenly stricken from them, be
if
47
sufficient to ohaptkk
than melted
bosom,
we might
kind to accompany
most
terrific
in its com-se.
it
nautical
works
and piled up the water
Gulf to the height of thirty
attempted to ride
to
it
high up on the diy land, and discovered that she had
let
go her anchor among the tree-tops on
The Florida Keys were inundated many
§
gj
Key.
Elliott's
feet; and, it is
the scene presented in the Gulf Stream was never
sm-passed in awful sublimity on the oceaa
thus
gQ
abated, she found her-
self
said,
§
in the
The Ledbury Snow
feet.
When
it out.
known
borders.
its
us of a stomi which forced this
tell
its sources,
itsiiabiiitT
Accordingly, the
that rage on the ocean have been
stream back to
in § 79
expect stonns of the most violent
spend their fury within or near
Our
1-
iron.
With such an element of atmospherical disturbance its
—
the column of superincumbent atmosphere hotter
dammed up
The water wonder-
said to have rushed out with
is
ful velocity against the fury of the gale,
producing a sea
that beggared description.
The "great hurricane" of 1780 commenced at Barbadoes.
In
it
was blown from the
the bark
the fruits of the earth destroyed
trees,
and
the very bottom and
;
depths of the sea were uprooted, and the waves rose to such a height that forts and castles were washed away,
and
their great
guns carried about in the air like chaff;
houses were razed,
men and in
aliips
beasts lifted
the storm.
At
were wrecked, and the bodies of
up
the
twenty thousand persons
in the air different
and dashed to pieces
islands,
lost their lives
farther to the north, the " Stirling Castle"
not
less
on shore
and the
;
"
than while
Dover
Great har-
17^"*
°
THE PHYSICAL GEOGRAPHY OF THE
48
men-of-war went down at
CHAPTER Castle"
sea,
and
SEA. fifty sail
were
driven on shore at the Bermndas. 82
Several years ago, the British Admiralty set on foot
Admiralty
as to the cause of the storms in certain parts inquiries ^ ^
§ British
investiga-
of the Atlantic, which so often rage with difistrous effects
ton.
The
to navigation.
may
result
summed up
be
conclusion to which the investigation led
by the
occasioned
in-egularity
in the
that they are
:
between the temperature
of the Gulf Stream and of the neighbouring regions, both
and water. The habitual dampness
in the air
83
§
Dampness of English
wcU
jgi^nds, as '
of the climate of the British
of that alonfj as the occasional dampness ^
§ 124.
«
§ 149,
'
§ 144.
THE PHYSICAL GEOGRAPHY OF THE
78 en A PIER of
the sun to create a polar and equatorial flow of
were Bi.n
on the
its
power confined simply
to a
which increases
stances
sun
air.
But
change of level
still
its
more power
mobility, to put
and gives the heat of the
it
in motion,
as heat changes the atmospherical level,
'
air,
the atmosphere has been invested with another property
supposed
Specific
SEA.
and it
the specific gravity of the air acted upon.
it
is
this
therefore,
If,
the level of the great aerial ocean were undisturbed
the sun's rays, and
if
:
changes aLso
by
the air were adapted to a change
of specific gravity alone, without any change in volume, this quality
would
also
be the source of at least two
systems of cmrents in the lower.
air,
namely, an upper and a
The two agents combined, namely, that which
changes level or volume, and that which changes gra\-ity, give
specific
us the general currents under consideration.
Hence we say that the priTnum mobile
of the air
is
derived from change of specific gravity induced by the freezing temperature of the polar regions, as well as from
change of
specific gravity
due the expanding force of the
sun's rays within the tropics. §
154
Con-
Therefore, fairly to appreciate the extent of the influence
due the heat of the sun in causing the winds,
it
should be
elusions. _
recollected that
we may with
as
much
reason ascribe to
the inter-tiopical heat of the sun the north-west winds,
which are the
jirevailing
winds of the
regions of the southern hemisphere,
extra-tropical
or the
south-west
winds, which are the prevailing winds of the extra-tropical regions of the northern hemisphere, as
we may
winds, whicli blow in the o[)posite directions. cal, therefore,
the trade-
Paradoxi-
as it seems for us to say that the heat of
the sun causes the winds between the parallels of 25' or
THE ATMOSPHERE.
79
80° north and south to blow toward the equator, and chapteb III.
that
it also
causes the prevaihng winds on the polar sides
of these same parallels to blow toward the poles,
j^et
the
paradox ceases when we come to recollect that by the process of equatorial heating
and polar cooling which
is
going on in the atmosphere, the specific gravity of the air is
as well as changed '^
Nevertheless, as Halley
its level.
_
said, in his
in
paper read before the Royal
1686, and as we also have
hard to conceive
why
said,^ " it is
London
Hkewise very
the limits of the trade-wind should
be fixed about the parallel of latitude 80° globe,
Haiieys veuiuiks.
_
Society in
all
around the
and that they should so seldom exceed or
fall
short
of those bounds."
Operated upon by the equilibrating tendency of the
§ 1,55
atmosphere and by diurnal rotation, the wind approaches How the north pole, for example, by a series of spirals from the south-west.
common
If
•
we draw
11about
a circle
ten'estrial globe,
and
intersect it
represent the du-ection of the wind,
wind enters and
all
this
that, consequently, there
calm
by
on a
as wind,
and
disc, therefore,
shall see that the
should be about the poles a
which the
air ceases to
ascends as in a calm
;
about
there should be a whirl, in which
At
or against the hands of a watch.
left,
the south pole the
winds come from the north-west,^ and consequently there they revolve about
it
udth the hands of a watch.
this should be so will be obvious to
will look at the arrows
Cancer and
poie.
spirals to
the ascending column of air revolves from right to
That
proachea nortli
1
parts of this circle from the south-west,
disc or circular space of calms, in
move forward
we
•
1
this pole
Capricorn *
any one who
on the polar sides of the calms (Plate
§ loo.
I.)
«
§ 137.
These
arrows are
&Jui!ipoid
THE PHYSICAL GEOGRAPHY OF THE
80 CHAPTER
—
'-
§
intended to represent the prevailing direction of the wind at the sm-face of the earth on the polar side of these calms.
between these two
It is a singular coincidence
156
Singular
SEA.
and other
tlius dcduccd,
facts
which have been observed
facts
foincid-
by
Bedfield, Reid, Pidding-
ence re-
and which have been
rotatoiy
ton,
whirl-
in the northern hemisphere revolve as do the whirlwinds
and
set forth
namely, that
others,
about the north
pole,
all circular gales in
many
of the rotatory storms
namely, from right to
left,
and that
the southern hemisphere revolve in the
opposite direction, as does the whirl about the south pole. §
How
157
can there be any connection between the rotary
motion of the wind about the of §
158
That there
pole,
by
in a gale caused here
it
and the rotary motion
local agents
?
probably such a connection has been
is
suggested by other facts and circumstances, and perhaps I shall
be enabled to
treat
of these
farther^ into Heat not
make myself
facts
when we come
clearer
and circumstances, and
to
to
inquire
the relations between magnetism and the
circulation of the atmosphere
for,
;
although the theory
the sole
sKcntof
of heat satisfies the conditions of the problem,
winds.
f
.
heat, doubtless,
is
^
'
^
the circulation of the atmosphere, yet
appear that §
159
Offices of
Some of see
how
the atmosphere moves
;
.
to perform,
alluded to
time, to consider sea,
;
keeping up
—So
far,
,
oi
and they are many.
some of them
1
we
but the atmosphere, like
every other department in the economy offices
and though
can be made to
Meteorological Agencies.
the atmo-
jphere
it
not the sole agent.
it is
its
m •
(>
one of the chief agents
but
I
.
nature, has its I
liave already
only propose, at this
some of the meteorological agencies
at
which, in the grand design of creation, have probably
been assigned to
this
wonderful machine. 1
As
at §299.
L
THE ATMOSPHERE.
To and
81
distribute moistiu'e over the surface of
temper the climate of different
to
by J
offices assicmed seem, are two great b o the ocean and the air. '
earth, chapteb
tlie
latitudes, it
—
would
their Creator to
,
.
On moistureand climate.
When
the north-east and south-east trades meet and
produce the equatorial calms,^ the reaches this calm belt,
hemisphere
in each
upward
direction.^
a portion of
;
§
ipi
it constant
heavily laden with moisture, for
is
tionin
no room for escape but in the
It has
cooler
by the time
has travelled obliquely over a large
it
space of the ocean.
air,
It
expands as vapour
its
comes down in the shape of
and becomes
it
ascends,
is
thus condensed, and
Therefore
rain.
it
is
that,
under these calms, we have a region of constant precipita-
Old
tion.
such dead calms of long con-
sailors tell us of
Singii:ar fact.
tmuance
here, of such
heavy and constant
have scooped up fresh water from the sm'face of the
The conditions
which
to
this air is
the moisture that
it
sea.
exposed here under
the equator are probably not such as to cause ])itate all
they
rains, that
it
has taken up in
its
Let us see what becomes of the
for Natui-e, in her
economy, permits nothing to be
;
taken away from the earth which to
is
162
§
1
long
sweep across the waters. rest
§
to preci-
not to be restored
again in some form, and at some time or other.
it
Consider the sippi,
gi-eat rivers
We
the
Amazon and
the Missis-
them day after day, and discharging immense volumes of water
for example.
year after year,
—
see
03
Amazon '^
sipU
into the ocean.
"AH (Eccl.
i.
the livers run into the sea, yet the sea 7).
Where do
where do they come from
you
will say.
?
They come from
But whence are »
is
not full"
the waters so discharged go, and
§ 135.
their sources,
their sources supplied
»
§ 136.
?
for,
whenr.o sources
^"^^
'^
'^
THE PHYSICAL GEOGRAPHY OF THE
82
what the fountain senda
CHAPTER unless
—
-
§
again,
1
164
precipita-
it
We
will fail
and be
SEA.
forth be returned to
by
see simply, in the waters that are discharged
thcse rivers, the
it
diy.
amount by which the
precipitation exceeds
Hon exceeds evapoiation.
the evaporation throughout the whole extent of valley
,•••,,
drained by them
amount
...-rI
ii
;
of water that falls from, or
atmosphere, whether as dew, rain, §
165
The
is
the total
deposited by the
hail, or
snow.
springs of these rivers^ are supplied from the rains
of heaven,
and these
are taken
up from the
rains are formed of vapours sea,
that "
it
be not
earned up to the mountains through the "
mean
and by precipitation
Note the place whence the
which
full,"
and
air,
rivers come, thither they
retiu'n again." §
1
(36
Waters
nf
Behold the St.
how the waters
Lawrcucc, and
of the
ia'tpi
rivers car-
and Asia,
Amazon, of the
Mississippi,
the great rivers of America,
all
ii
i
i
up by the atmosphere, and
riedback
Luropc,
sources,
flowiug in invisible streams back through the air to their sources
among
lifted
the
hills,"
and that tlirough channels
so
regular, certain, and well defined, that the quantity thus
conveyed one year with the other for that is the
quantity which
the ocean through
tliese rivers
annually by each river
is,
;
we
is
see
nearly the same
:
running down to
and the quantity discharged
as far as
we can
judge, nearly
a constant. §
167
Order and
We now ^
in
of^tmo-
;
and, though
it is
apparently so
'^
arrange-
ment
begin to conceive what' a powerful machine
the atmospheve must be capricious
and wayward
of order and pi'oof
_
in
_
its
movements, here
evidence
arrangement which we must admit, and
which we ainnot deny, that
office Avith
is
regularity
*
and § 112.
it
performs this mighty
certainty,
«
§ 112.
and
is,
therefore, as
THE ATMOSPHERE. law as
o1>edient to
is
83
the steam-engine to the will of
its chapter
builder.
L
It, too, is
all their
an engine.
The South Seas themselves,
in § 168
vast inter-tropical extent, are the boiler for
and the northern hemisphere
is
condenser.
its
it,
Comparison with
The
thestenai Gil trine
mechanical power exerted by the air and the sun in ing water from the earth, in transporting place to another,
and
in letting
ceivably great.
The
utilitarian
power that the to machinery,
astonished
is
which are required
Yet what steps, in
to
lift
is
at the
incon-
water-
afford if applied
number
of figures
to express its equivalent in horse-power.
the horse-power of the Niagara, falling a few
and
as high as the clouds
the water that river,
would
comparison with the horse-power that
up
from one
it
it down again, is who compares the
Falls of Niagara
lift-
is
but by
let
is
required
down again
all
discharged into the sea, not only by this other rivers in
all
The
the world.
cal-
made by engineers, and, according to it, making and lifting vapour from each area of
Caicuia-
dilation has been
force re-
the force for
lifting va-
one acre that
is
included on the surface of the earth
is
me
earth,
equal to the power of 80 horses, and for the whole area of the earth
power
it
is
800 times
greater than
vapour
makes
all
the water-
in Europe.
Where does
the
that
the rains ivhich § 169
feed the rivers of the northern hemisphere come
from
?
The proportion between the land and water in the
Difference propor-
.of
northern hemisphere
is
that obtains between
very different from the proportion
them
m
the
southern.
In the
tion be-
tween land anu water
northern hemisphere, the land and water are nearly equally em divided.
In the southern, there
water than land.
is
several times
more
All the great rivers in the world are
and
he tiemi'^'®"'^-
—
;
THE PHYSICAL GEOGRAPHY OF THE
84 CHAPTER in the '-
northern hemisphere, where there
Whence, then, are
supply them. Tliose of the
River
Amazon
equatorial calms
and trade-winds of the
mark.
always near
both hemispheres,
and as
line,
tributaries
its
supplied with water
high-water
Amazou,
only great
is
Boutheni
no large river in
made
of vapour
Taking the
sphere,
give rise to none, nor
the ouly gi'eat river of the southern hemisphere.
New
is
and
rivers of
we know
of
North America and North
the northern hemisphere.
How
that the evaporating surface is
it,
is
there one in South Africa entitled
the rivers of Europe and Asia,
hemisphere —how
There
The South Sea Islands
Holland.
to be called great that
all
It dis-
come from
out of the count, the Rio de la Plata
Riodeia
therefore,
its
northern tributaries
taken up from the Atlantic Ocean.
'^^16 gi'eat
;
it
cannot be said to belong exclusively
it
It is
to either.
its
southern for the other half
its
charges under the
is
It is
For one half of the year
are flooded, and
170
That
Atlantic.
come from the north and south
a river without periodic stages of a
it is
very marked character.
§
ocean to
always the rainy season on one side or the other of
consequently,
that
is less
their sources replenished?
are supplied with rains from the
river runs east, its branches it is
SEA.
I
lies
is
it,
lie
then, considering
mainly
say, that
we
Africa,
wholly within
in the southern
should have the
evaporation to take place in one hemisphere and the con-
The
Greater
densation in the other
rX^faiia"
falls in the northern hemisphere
?
which
amount of rain which much gi-eater, meteorol-
total is
the southern.
Tlie
ern"hemi-
ogists tell US, than that
southeri^"
annual amount of rain in the north temperate zone half as
5
171
much
How is
it,
falls in
is
again as that of the south temperate. then, that this vapour gets, as stated,^ from
§170.
tlie
THE ATMOSPHERE.
85
southern into the northern hemisphere, and comes with chapteb
—
such regularity that om* rivers never go diy and our springs
not
fail
and the
compensation of
exq\iisite
the atmosphere.
It
winter,
and
in early spring, the
\vith the greatest intensity
southem hemisphere, and
sun
is
down upon
tnis
pouring his rays
gphe°re
the seas of the
the^ionu-
we
f™mVh"
powerful engine which
pumping up the water there^ for our with the greatest activity. At this time, the mean
are contemplating rivers
and wonderfully coun-
exquisitely
is
giund machine,
this
Late in the autumn of the north, throughout how the
terpoised. its
-
It is because of the beautiful operations
?
is
temperatm'e of the entire southern hemisphere
jp^g''""
said to
is
be about 10° higher than the northern.
The heat which latent,
this
heavy evaporation absorbs becomes
and, with the moisture,
upper regions of the atmosphere mi til
Here the vapoui' state of it is
vapour
is
It clouds
172
reaches our climates.
formed into clouds, condensed, and
set free, it
that which contributes so
climate.
we
is
it
The heat which held
precipitated.
§
earned through the
is
up
water in the
this
becomes sensible heat, and
much
to
in winter, turns
are going to have falling weather.
temper
oiu*
winter
warm, and we say That
because
is
Processor coiidensa-
the
process
of
condensation
this southern heat that has
of the sun
m
by the
sea,
has
may have
though no rain or snow
already fallen
:
commenced, thus
we
tion.
feel
been collected from the rays
been bottled away by the winds
the clouds of a southern summer, and set free in the
process of condensation in our northern winter. If Plate
I.
fairly represent the course
the south-east trade- winds sphere, and, as
an upper
of the
current, bear into
_^^____________ ^
winds,
woidd enter the northern hemi-
§ 169.
it
all
their
§
173
trade-"^^'
thTir^moi" ture into northern
hemi•Inhere.
THE PHYSICAL GEOGRAPHY OF THE
86
CEAPTER moisture, except that
which
SEA.
precipitated in the region of
is
in.
equatorial calms. §
The South
174
Hypo-
^
thesis.
it
;
mainly the water
Seas, then,^ should supply
noiihem hemisphere condenses
for this enoine, while the
\
' .
we
have more rain in the northern
should, therefore,
The
liemisphere.
on the land
we have
rivers tell us that
—
at least
for the great water-courses of the globe,
:
and
half the fresh water in the world, are foimd on our side
This fact alone
of the equator.
strongly corroborative
is
of this hypothesis. §
The rain gauge
175
tells
The
us also the same story.
Confirmed fy rain
yearly average of rain in the north temperate zone
gauge.
according to Johnston, thirty-seven inches.
.
,
•
tt
gives
The observations
but twenty-six in the south temperate.
Log-
of mariners are also corroborative of the same.
upward of
books, containing altogether the records for
260,000 d&js
examination of log-
gales,
therein recorded
number
for the north
than
examination
is
.
of each
it is
northern hemisphere, ^vith southern, with
its
its
shows the status
it
unstable
in
Rains, and fogs,
and storms,
their occurrence
result of this
the
excess of land, than in the
all
and are more irregular
and place of
The
much more
excess of water.
thunder, and calms, frequently,
•
for the south.
be
and
Propori i n given as decidedly greater .
is
very instructive, for
of the atmosphere to
of calms, rains,
each hemisphere.
for
,
tionally the
south,^
for the purpose of ascer-
number
taining, for comparison, the Result of
Ocean north and
in the Atlantic
have been carefully examined
is,
•
He
i
on
occur
also
as to the
this side,
and
much more time
than they are
on the other side of the equator. §
17G
Moisture
is
1
never extracted from the According to
§ 16S.
«
aii*
by subjecting
Plate XIII.
87
THE ATMOSPHERE. it
from a low to a higher temperature, but the
Thus
all
reverse, chaptek
—
the air which comes loaded with moistm-e from T
the other hemisphere, and
1
•
•
•
ii
I
-ii
i_i
borne into this witli tbe
is
south-east trade-winds, travels in the upper regions of the
atmosphere^ until
it
reaches the calms of Cancer
here
;
'-
Moisture never essubjecting
it frmn a
becomes the surface wind that prevails from the south-
ward and westward. As it goes north it grows cooler, and the process of condensation commences. We may now liken it to the wet sponge, and the
i.a»
tempefl-'" '"'''•
§
177
decrease of temperature to the hand that squeezes that
Finally reaching the cold latitudes, all the mois-
sponge.
ture that a dew-point of zero, and even far below, can
from
extract, is wi'ung
it
" to return according to
And
here
wmd
1
we
•
dnveth away ram.
dry atmosphere.
hib circuits" as
nil
>>
commences
this air then
quote Scii]tture again
can
1
•
and
;
•
Ihis
:
The
"
•
is
nortli 1
•
1
/•
a meteorological tact
imr)-.onto suppose that the
south-east trade-winds,
^^^®
when they
and ascend,
calms Q^ equatorial ^
is,
ia
that
arrive at the belt
and continue
cross over
trade-
their course as
crossatthe
while the air that the north-east trade-winds discharge
calm
an upper
ciu-rent to
the calms of Cancer,
belts.
into the equatorial calm belt continues to go south, as
upper current bound for the calms of Capricorn.
what should cause
this
wind
to cross over
an
But
Why should
?
there not be a general mingling in this calm belt of the air
why
brought by the two trade-winds, and
should not
that which the south-east winds convey there be its ascent, to
302
In the
after
flow off either to the north or to the south,
as chance directs §
left,
?
was
first place, it
the grand design
;
my
at variance with
for I could not bring
faith in
myself to believe
that the operations of such an important machine as the
atmosphere should be
Yet
I
knew
chance, even for a moment.
left to
of no agent which should guide the
across these calm belts,
and lead
side opposite to that on
which
certain circumstances
seemed
it
wind
out always on the
it
entered
;
nevertheless,
to indicate that such a cross-
ing does take place. §
303
iivifience ill
Evidence in favour of
seemed
be afforded by this
to
circumstancc, namely, our researches enabled us to trace
favour
of tins sup-
it
n
-i
1
1
• .
from the belt of calms, near the tropic extends entirely across the
seas,
an
y^
j^
efflux
•
i
Lancer, which
oi
i
of air both to
the north and to the south; from the south side of this belt the air flows in a never-ceasing breeze,
north-east trade-winds, toward the equator.
On
the north side of
it,
called the
(Plate
I.)
the prevailing winds come
1
MAGNETISM AND CIRCULATION OF THE ATMOSPHERE. from
They
but they go toward the north-east.
it also,
137 chaptek
—
are the well-known south-westerly winds which prevail
.
along the route from this countiy to England, in the ratio
But why should we suppose a crossing
of two to one.
to
take place here?
We fToino-
suppose
because these last-named winds are
so,
from a warmer to a colder climate, and therefore
may be inferred that know she exacts from but on a smaller
natm-e exacts from them what
§
304
§
305
it
we
the air under similar circumstances,
scale, before oui- eyes,
namely, more pre-
cipitation than evaporation.
But where,
it
may
be asked, does the vapour which
these winds carry along, for the replenishing of the whole whence extra- tropical regions of the north,
m
They did
come from?
.
came along
comes the vapour for replenish-
.
the upper regions, a
ingtiie ex-
counter-current to the north-east trades, unless they eva-
cai regions
not get
it
as they
porated the trade-wind clouds, and so robbed those winds of their vapour.
They
certainly did not get
from the
it
sm-face of the sea in the calm belt of Cancer, for they did
not tarry long enough there to become saturated with moisture.
Thus circumstances again pointed
to the south-
east trade-wind regions as the place of supply.
Moreover, these researches afforded grounds for the §306 supposition that the air of which the north-east trade- North-east ^ .
trade-
,
winds are composed, and which comes out of the same 1
.
1
/>
zone of calms as do these south-westerly winds, so tar
from being saturated with vapour at for
its
exodus,
is
near their polar edge, the north-east trade vnnds
for the
most
part,
dry winds.
dry; are,
Reason suggests, and phi-
losophy teaches, that, going from a lower to a higher temperature, the evaporating powers of these winds are
winds for *''
•
1
1
which
01
•
this
Region of precipitatiou.
considering as
impinges, ought to be a region of copious
first
precipitation.
Now, and
let
us turn to the works on Physical Geography,
what we can
see
and Johnston
find
upon
—department
In Berghaus
this subject.
Hyetography
—
it
is
§
344
Patagonia.
stated,
on the authority of Captain King, R. N., that upward of twelve feet (one hundred and
fifty- three inches)
of rain
fell
in forty-one days on that part of the coast of Patagonia
which
lies
within the sweep of the winds just described.
So much rain
falls there,
navigators say, that they some-
times find the water on the top of the sea fresh and sweet.
After impinging upon the cold hill-tops of the Pata-
gonian
coast,
and passing the snow-clad summits of the •
111down
1
Andes, this same wind tumbles slopes of the range as a dry
wind
upon the eastern
as such,
;
the almost rainless and barren regions of
cis-
it
§
345
Becomes a '^^ wind in Buenos
traverses
Andean Pata-
gonia and South Buenos Ayres.
These conditions, the direction of the prevailing winds,
and the amount of
precipitation,
may
be regarded as evi-
§
346
Evidence in favour
deuce afforded by nature, against,
if
not in favour
the conjecture that such
voyage of
this
may
vapour through the
air.
of,
certainly not
have been the
At any
rate,
of conjeo-
;
THE PHYSICAL GEOGRAPHY OF THE
150
immense quantity
CHAPTER here is proof of the
—
'-
SEA.
of vapour which
these winds of the extra-tropical regions carry along with
them toward the
poles
and
;
I
can imagine no other place
than that suggested, whence these winds could get so
much Theory.
I
vapour.
am
not Unaware of the theory, or of the weight
attached to
which requires precipitation to take place
it,
upper regions of the atmosphere on account of the
in the
cold there, irrespective of proximity to
snow-clad §
347
mountain tops
an(l
hills.
But the
and conditions developed by
facts
Facts irre-
of research upon the high seas are in
abie with
concileable with that theory.
many
this
system
respects irre-
With a new system
of facts
before me, I have, independent of all preconceived notions
and tions §
How
348 do
the currents of
opinions, set about to seek
and
These
for explana-
reconciliations.
may
not in
all cases
indeed, notwithstandincr o the '
be satisfactory to every one
amount
of circumstantial evi-
dcucc that has already been brought to show that the air "^
air cross
each other
among them
which
the
'-'
and the south-east trade-winds,
north-east
discharge into
the
ascending,
—
cross
belts
I.)
question, "
other?"
—
does,
in
and that from the northern passing
over into the southern hemisphere (see C, Plate
calms,
from the southern passing over
that
into the northern,
of equatorial
F
and G,
B and
yet some have implied doubt by asking the
How
And,
are
two such currents of
for the
want
of light
air to pass
upon
correctness of reasoning, facts, inferences,
each
this point, the
and deductions
have been questioned. §
349
tiUmbeJt!
In the equatorial
first
place, it
calms
is
may
be said in reply, the belt of
often several hundred miles across,
1
MAGNETISM AND CIRCULATION OF THE ATMOSPHERE. 151 seldom
than sixty
less
whereas the depth of the volume
;
chapter VI.
of air that the trade-winds pour into miles, for that
it is
only about three
supposed to be about the height to which
is
of tia-
Heat does not
most complete of non-conductors. it
demon
ice.
*'
meate water as
and flora ofthesia as depen-
capacities for heat are scarcely § 399
its
•'
393
The fauna
and the habitat
exceeded by those of any other substance,
conductors.
The polar
§
under the iceberg, or in
waters colder than the melting
Now
proclaims
out
the whales of the sea
inhabitants proclaim
all its
it
chapteh YH.
and that at the bottom remains
p«s
cool.
The heat passes through iron by conduction, but to get it requires to be conveyed by a motion,
through water
which
in fluids
we
call currents.
Therefore the study of the climates of the sea involves
a knowledge of
its currents,
both cold and warm.
They and
§
400
ledgeofit?
are the channels throucrh which the waters circulate,
necessary
by means
[n'„f"f^'
of which the harmonies of old ocean are pre-
''
served.
f^""'"'''
Hence, in studj'ing the system of oceanic circulation. '
§ TO.
M
T6
§
40I
THE PHYSICAL GEOGRAPHY OF THE
168 CHAPTER
—
we
set out
SEA.
with the very simple assumption, namely, that
VII
'-
from whatever part of the ocean a current
tion on
based the
to retm'u; for
cunents.
tlie
is
same part a current of equal volume
run, to
found to
bound
is
upon this principle is based the whole systcm of Currents and counter-currents of the air as well as of the water.
Currents of water, like currents of
402
§
v.'iiiri-
meeting from
air,
various directions, create gyrations, which in some parts
pools.
of the sea, as on the coast of
Norway, assume the appear-
ance of whirlpools, as though the water were drawn into
a chasm below. a
such
Beechey,
conflict E-.N.,*
The celebrated Maelstrom of
or other
tidal
is
caused by
Admiral
streams.
many
has given diagrams illustrative of
liotatory
" rotatory
En-iish CiuuuieL
which occur between the outer extremities of the channel
streams in the English Channel, a number of
and the stream of the oceanic or parent wave."
tide
are clearly to be accounted for," says he, "
"
They
by the streams
acting obliquely upon each other." §
403
Currents of the sea
can ran up
It is not necessary to associate with oceanic cuiTents
^^^
-^^gg^ ^j^g^^
«'
g^
stTOim
§
404
Those runiiing hito file .Seii
Rid and
Meditcrranean are the reverse
So
hiffher to a lower level.
case,
Z"' these.
Qj^jg^, of neccssitv, as ^^x^y •^
far
'
on land, run from
from
'
this
some currents of the sea actually run up
being the hill,
while
others inin on a level.
The Gulf Stream is of the first class.' The currents which run from the Atlantic into the MeditciTancan, and from the Indian Ocean into the Red Here the bottom of the curSea, are the reverse of this. rent is probably a water-level, and the top an inclined Take the Red Sea current as plane, running down hill. .
* See Eii;;lish
,
.
f^,
an interesting paper by hlin on Tidal Streams of the North Sea and Phil. Transactions, Part ii., 1351. i>\>. 703;
Channel.
I
S Q
-
CURRENTS OF THE an
That sea
illustration.
a rainless and rlverless
thus taken up It is
is
It
district.
it
most
may
m
Being
a long and narrow trough. the evaporation from
for the
lies,
169
SEA. part,
within chaptkr
—
VII.
be compared to
a rainless
-
district,
immense; none of the water
is
retui-ned to
either
it
about one thousand miles long;
by
rivers or rains.
nearly north
it lies
itssizeand latitude.
and south, and extends from latitude 13° to the parallel of 30° north.
From May
to October, the water in the upper part of
this sea is said to be
two
lower than
feet
it is
near the
§
405
Difference of level
This change or difference of level
mouth.*
ascribed to
is
m
"•
the effect of the wind, which, prevailing from the north at that season,
is
supposed to blow the water out.
But from May the season
when
to October
evaporation
is is
also the hot season; it is
going on most rapidly;
and when we consider how dry and how hot the winds are which
blow upon
we may suppose not
less,
certainly,
that amount.
§
406
immense '"•
this sea at this season of the year,
the daily evaporation to be immense;
than half an inch, and probably twice
We know
that the waste from canals
by
summer time, when taking the capacity of his feeders into With him it is an important calculation, has to consider. how element; much more so must the waste by evaporation from this sea be, when we consider the physical con-
evaporation, in the
is
an element which
the engineer,
ditions under
Sea, is
which
it is
Its feeder, the
placed.
a thousand miles from
burning sands; the evaporation
its is
head;
its
ceaseless;
the vapours, which the scorching winds that
carry away, are returned to •
it
Arabian
shores are
and none of
blow over
it
again in the shape of rains.
Johuston's Physical Atlas.
J^ficj^njl;
''""^
170
The Red Sea vapours are
CHAPTER
—-
THE PHYSICAL GEOGRAPHY OF THE carried off
SEA.
and precipitated
VII.
-
Cause of depression
The depression
elsewhere.
summcr
^^ ^^^ gffggj;
in Its leveL
in
tlie
time, therefore,
it
level of its
appears,
is
head waters
owing
as well as to that of the of evaporation ^
to the
wind blow-
ing the waters back. §
The evaporation
408
Supposed
parts of the Indian Ocean'
in certain
is
from three-fonrths of an inch to an inch
it
for tlic
evapoia
Red Sea
in the
summer time
tion.
Suppose ' '
daily. ''
averatre
to average '' ° only
^
an inch a day.
half §
409
Averac-e velocity of
current runnini; into
it.
Now,
we
if
suppose the velocity of the current which
runs iuto that sea to averacre, ° from mouth to head twenty milcs a day, it would take the water fifty days to reach ^ ''
»/
the head of
If
it.
by evaporation
it
daily,
lose half it
the Isthmus of Suez,
an inch from
would, by the time
its
surface
it
reaches
twenty-five inches from
lose
its
surface. §
410
waters lower at Its
Babehnan deb.
Thus the waters of the Red Sea ought ^|^g
to be lower at
Isthmus of Sucz than they are at the Straits of Babel-^
^^''^^i^isb-
Independently of the waters forced out by the
they ought to be lower from two other causes,
wind,
namely, evaporation and temperature, for the temperature of that sea
than §
411
Illustra-
it is
is
necessarily lower at Suez, in latitude 30°,
at Babelmandeb, in latitude
To make Sea
is
it
1 3°.
Red
quite clear that the surface of the
not a sea
level,
but
is
an inclined plane, suppose
tion.
the channel of the
and
level floor,
Red Sea
to
have a perfectly smooth
with no water in
it,
and a wave ten
feet
high to enter the Straits of Babelmandeb, and to flow up the channel at the rate of twenty miles a day for days, losing daily,
by evaporation,
to perceive that, at the
end of the §33.
half an inch
;
fifty
it is
fiftieth day, this
easy
wave
.
CURRENTS OF THE would not be so high, by two
171
SEA.
feet (twenty-five inches), as chapteb
— VIX.
it
was the
day
first
The top
it
commenced
of that sea, therefore,
inclined plane,
made
so
to flow.
may
be regarded as an
But the salt water, which has lost so much of its freshness by evaporation, becomes Salter, and therefore heavier. The liffhter water at the Straits cannot balance the heavier water at the Isthmus, and the colder and Salter, and theremust
fore heavier water, rent, or it crystals,
must deposit
and thus
make
either run out as
make
Red Sea
brine
infer that there is
Red
is
know
going on.
that
Hence
from the Red Sea an mider or outer
from the Mediterranean through " the waters near Straits of Gibraltar, and that the surface
current,' as there
is
Suez are
than those near the mouth of the Red
salter
413
the salt from the
all
—and we
neither the one process nor the other
we
§
an under cur-
the bottom of the
must abstract
it
the
412
sm-plus salt in the shape of
its
gradvially
Sea a salt-bed, or ocean to
§
by evaporation.
pf^^,^'""^®
"'"^^ current
^°'"J''^
Red
S;;x
Sea.
And, to show
why
there should be an outer and under
current from each of these
two
seas,
let
us suppose the
case of a long opening o trough, o o into a vat of 1 '
oil,'
with a
partition to keep the oil from rrmning into the trough.
Now
suppose the trough to be
filled
up with wine on
one side of the partition to the level of the other.
The
water as
it
oil
is
and
by evaporation, and
heavier.
on the
enters either of these seas from the ocean,
and the wine the same water freshness
oil
introduced to represent the lighter
Now
what would take
after it has lost
therefore has
some of
become
its
salter
suppose the partition to be raised,
place
?
Why,
the
oil
would run
in as
§
414
"g^^^"'
"pperand under cur. '"^"'^
THE PHYSICAL GEOGRAPHY OF THE
172 ,'HAPTER
an upper current, overflowing the wine, and the wine
would run out as an under
1
The
415
§
rivers
current.
which discharge
in the Mediten-anean are
not Sufficient to supply the waste of evaporation, and
Beautiful
cnnipensa- is
which
.
by a pfoccss ,
„
,
Similar to .
,
preserves
ricd lu irom the ocean
brium of
were
it
solid
not
so,
1-1 this that
••!
Bvstem of tion
SEA.
^
•
^
^
the salt which -,
is
it
•
car-
is
,
returned to the ocean again;
the bed of that sea would be a mass of
The equilibrium
salt.
1
of the seas
is
preserved,
beyond a doubt, by a system of compensation as exquiby which the
sitely adjusted as are those
spheres" §
416
It
is
immense
music of the
maintained.
difficult to
is
"
form an adequate conception of the
quantities of solid matter, in solution, which the
current from the Atlantic carries into the Mediterranean.
In the abstract log
for
March
1855, Mr. William
8th,
Grenville Temple, master of the United States ship Levant,
Extract
homeward bound, has described "Weather fine; made 1|
ofc.s.ship
stood in to Almiria Bay, and anchored off the village of
Roguetas.
the indraught there:
At noon,
lee- way.
pt.
Found a great number
of vessels waiting for
a chance to get to the westward, and learned from them that at least a thousand sail are weather-bound between this
and
Some
Gibraltar.
of
them have been
so for six
only to
weeks, and have even got as far as Malaga,
be swept back by the current.
Indeed, no vessel has
been able to get out into the Atlantic
for three
months
past." §
417
stroncurrent
Now, suppose back
this
this fleet for so
current,
many
which
and beat
baffled
days, ran no faster than
two
in-
to the
knots the hour.
Mediterraneaa.
and
Assuming
its
depth to be 400 feet only, .
itii
widtli seven miles,
and that
it
.
,
.
•
i
carried in with
•
it
CURRENTS OF THE
the average proportion of solid matter
—
contained in sea water
173
SEA.
—say one
thirtieth chapter
—
VII. -
and admitting these postu-
;
hites into calculation as the basis of the computation, ittionasto
appears that
salts
enough to make no
less
than 88 cubic
miles of solid matter, of the density of water, were carried into the Mediterranean during these
were some escape
unless there
for all this
which has been nmning into that merely, but for ages,
ranean would, ere
it
sea,
Now,
days.
soHd matter,
not for 90 days
very clear that the Mediter-
crystals.
Let us see the results of actual observation apon the
Red Sea and
density of water in the •'
the MediteiTanean,
'
and upon the under currents that run out from these ^ SeaS.
Four or
cm-^
""'
have been a vat of very strong
this,
bed of cubic
brine, or a
is
90
sait ear-
JJfig
five years ago,
Mr. Morris, chief engineer of
§
418
^^™'^y
§
419
the Oriental Company's steam-ship Ajdaha, collected spe-
cimens of Red Sea water
all
by Dr. Giraud, who reported Latitude.
D
No. No. No. No. No. No. No.
the
way from Suez
to the
Babelmandeb, which were afterward examined
Straits of
1.
2. 3.
Sea at Suez Gulf of Suez Red Sea
the following results:* Longitude.
greea.
—
Spea Grav.
Degrees.
Saline Coat. 1000 p«rU,
27.49
33.44
1027 1026
40.0
24.29
36.
1024
39.2
1026 1024 1024 1023
40.5
4.
do.
20.55
38.18
5.
do.
20.43
6.
do.
14.34
40.03 42.43
7.
do.
12.39
44.45
41.0
mouth
of the
Red
Sea,
Bombay Geograph. Soc,
toI. is.,
May
Giraud.
39.2
and show that the surface waters at the head are heavier and Salter than the surface waters
* Transact, of the
by Dr.
39.8
tions just annoimced,
at the
Results reported
39.9
These observations agree with the theoretical deduc-
1849 to August 1850.
°'
water in '^edsea and Medlterraneaa
§
420
THE PHYSICAL GEOGRAPHY OF THE
174 criAPTKK
SEA.
In the same paper, the temperature of the
air
between
"and
Suez and Aden
often rises,
^ ^ Tempera-
bablv averasres
little less
tureofair
yg^r round.
Suez and
g5° ^g 85°, and the difference between the wet and dry
'-
JO
The
is said,
it
90°,
to
and than 75° day ^
bulb thermometers often amounts to 2 5° Average
or dcscrt wiuds, to from 30° to 40°
tiou.
ration at
Aden
;
—
the
"^
_
_
in the kamsin,
the average evapo-
about eight feet for the year."
is
gi-eater
the evaporation of
"
assuming," says Dr. Buist,
Sea to be no
niorht all o
surface of this sea varies in heat from
'
A ilea.
pro-
Now, the Red "
than that of Aden, a sheet of water
eight feet thick, equal in area to the whole expanse of Assump-
be carried off annually J in vapour I
t,hat sea, will '
tiou of Dr.
: >
or,
assum-
'
_
ing the
Buist.
average
Red Sea
most —and — whole this,
the
the fact
hundred
to be eight
of
assuredly,
it
feet in is
depth at an
more than double
would be dried
up,
were no
water to enter from the ocean, in one hundred years.
The waters of the Red Sea, throughout, contain some or, as salt is a half four per cent, of salt by weight or, in heavier than water, some 2.7 per cent, in bulk
—
round numbers, say three per
cent.
—
In the course of
three thousand years, on the assumptions just made, the
Red Sea ought
to
have been one mass of
solid salt,
if
there were no current running out." §
422 '*
Now we know sand years
old,
tinee^*''
thoiisan.i
years
old.
the
Red Sea
and that
it
is
423
l\'.[^'[l^'
cu: rents,
;
currents bring that as fast as the upper ° the ' salt in at the top, the under ciuTents carry it out at the
^hc rcasou
is,
^
bottom. §
more than three thounot filled with salt and
is
Mediterranean Currents.
—With
current from the Mediterranean, j,,^.
|.j^jj^^
^y^,
j^^Q^y that tlicrc
is
regard to an under
we may begin by remarka cm-rent always setting
1
CURRENTS OF THE li:
SEA.
]
and that
at the sm-face from the Atlantic,
this
is
a salt- chaptes
water current, which carries an immense amount of
We
into that sea.
salting
up
and
;
know, moreover, that that sea
75
is
—
salt
not
therefore, independently of the postulate,^
and of observations, we
the existence of an
niio^ht infer
Existence of an
under current, through which this .
into the broad ocean
With regard
salt finds its
way
out
to this outer
under current
.
again.'*'
inferred
and under
cuiTent,
we have
observations re-
observations telling of "
existence as long ago as 1712. gardingu
its
In the year 1712," says Dr. Hudson, in a paper com-
municated to the Philosophical Society ^
in 1724-, "
''
sieur
du
L'Aiffle, that fortunate *=
and srenerous
Moncommander
=>
chase near Ceuta Point to a Dutch ship bound to Holland, in the middle of the
Gut between
Tariffa
and Tangier, and there gave her one broadside, which
sunk
du L'Aigle
;
men
her, all her
and a few days
being saved by Monsieur the Dutch ship, with
after,
* Dr. Smith appears to have been the first to con/ec^wre this explanation, which he did in 1683 {vide Philosophical Transactions). This continual indraught into tlie Mediterranean appears to have been a vexed question among the navigators
and philosophers even of those times. Dr. Smith alludes to several hypotheses wliich had been invented to solve these phenomena, such as subterraneous vents, canties, exhalation by the sun's beams, &c., and then offers his conjecture, vhich, in his own words, is, " that there is an under current, by which as great a quantity of water
what
is
carried out as comes flowing
have said above about the
in.
To confirm which,
besides
and at the shore in the Downs, which necessarily supposes an under current, I shall present you with an instance of the like nature in the Baltic Sound, as I received it from an able seaman, who was at the making of the trial. He told me that, being there in one of the king's frigates, they went with their pinnace into the mid stream, and were carried violently by the current; that, soon after this, they sunk a bucket with a heavy cannon ball to a cei-tain depth of water, which gave a check to the boat's motion and, sinking it still lower and lower, the boat was driven ahead to the windward against the upper current the current aloft, as he added, tvjt being over four or five fathoms deep, and that the lower the bucket wa* let fall, they found the under current the stronger." I
diflference of tides in the ofiing
;
:
»
§ 401.
P'pei-by
^
of the privateer called the Phoenix, of Marseilles, giving
directly
424
Extract from a Dr. H4id-
,
came up with her
§
son.
— 1
THE PHYSICAL GEOGRAPHY OF THE
76
OHAPTEK lier cargo of '•
which
gier,
place
brandy and
is
oil, ai'ose
on the shore near Tan-
at least four leagues to the
where she sunk, and
SEA.
westward of the
directly against the strength of
the current, which has persuaded
many men
that there
is
a recun-ency in the deep water in the middle of the Gut that sets outward to the grand ocean, which this accident
very much demonstrates the water which
several of the
§425 Dr. woi-
observa tions on
density,
mentioned
;
otherwise,
have been driven towards Ceuta,
The water
in the
Gut must be very
deep,
commanders of our ships of war having
attempted to sound contrive,
the Straits returns that way,
coasts before
this ship must, of covu'se,
so upward.
and, possibly, a great part of
inins into
and along the two and
;
it
with th^ longest lines they could
but could never find any bottom."
In 1828, Dr. Wollaston, in a paper before the Philosophical Society, stated that he found the specific gravity
of six hundred of a spccimcn of sea water, from a depth ' ^
and scvcuty fathoms, " density
have a
fifty
miles within the Straits, to
exceeding that of distilled water by
more than four times the usual leaves,
excess,
and accordingly
upon evaporation, more than four times the usual
Hence
quantity of saline residuum.
it
is
clear that
under current outward of such denser water,
if
an
of equal
breadth and depth with the cuirent inward near the surface,
would cany out
much salt below as moved with less than
as
in above, although it
is
brought
one-fourth
part of the velocity, and would thus pi'event a perpetual increase of saltness in the Mediterranean Sea
beyond that
existing in the Atlantic." §
426
The doctor obtained Captain,
this
specimen of sea water from
now Admiral Smyth,
of the English navy,
who
CURRENTS OF THE had
collected
it
177
SEA.
Dr. Marcet died before
for Dr. Marcet.
chaptf.k VII.
receiving
and
it,
it
some time before It
had remained
came
it
hands
in the admiral's
into those of Wollaston.
may, therefore, have
lost
something by evaporation;
for it is difficult to conceive that all the river water,
§
427
and
three-fom-ths of the sea water which runs into the Mediterranean,
evaporated from
is
under current having
foiir
leaving a brine for the
it,
times as
much
salt as the
Very
at the surface of the sea usually contains.
M. Coupvent des Bois •
1
is
said to
recently,
observation of M.
have shown, by actual
coupvcnt
f
•
1
water
observation, the existence oi an outer
IT
'^'^^
Bois.
and umler current
from the Mediterranean.
However
may
that
be, these facts,
and the statements §428
of the Secretary of the Geographical Society of Bombay,^
seem
no room to doubt as to the existence of an
to leave
Factsieavt as to the
existence
under current both from the Red Sea and Mediterranean,
ofanumier current
and as to the cause of the surface current which flows into them.
accounted
think
I
it
a matter of demonstration.
It
is
by the salts of the sea. Writers whose opinions are entitled to great respect
differ tion.
for''
with
me
as to the conclusiveness of this demonstra-
Amonor these writers are Admiral Smyth, of the "^ ,
British navy,
each other. in
and Sir Charles
who
Lyell,
.
also differ
§
42
'J
Difference of opinion in regard
toit.
with
1820, Dr. Marcet, being then engaged
In
studying the chemical composition of sea water, the
admiral, with his usual alacrity for doing " a kind turn,"
undertook to
collect for the doctor si)ecimens of ^
Mediter-
ranean water from various depths, especially in and about the Straits of Gibraltar. fifty
Among
these
was the one taken
miles within the Straits from the depth of six hun-
dred and seventy fathoms (four thousand and '
«•
421.
»
§ 413. 12.
»
g
425.
specimens of water
twenty
collected rai
smyth.
THE PHYSICAL GEOGRAPHY OF THE
178 CHAPTER feet), y
SEA.
common
which, beinoj o four times salter than '
VII.
water,
as
left,
we have
^
just seen, no doubt in the
sea
mind
of
Dr. Wollastou as to the existence of this under cm-rent of brine. §
430
Depti: in
the Straits.
... But the
indefatigable admiral, in the course of his cele-
bratcd survey of the Mediterranean, discovered that, while
was upwards of nine hun-
inside of the Straits the depth
fathoms, yet
di-ed
in
the Straits themselves the depth
across the shoalest section
is
not more than one hundi'ed
and sixty* fathoms, sircharios Lyell's rte(luctions.
«
Such
bcincr ° the
we can now
casc,
prove," exclaims ^
_
Sir Charles Lyell, " that the vast
amount
of salt brought
agam by
into the Mediterranean does not pass out Straits
;
for it appears
the
by Captain Smyth's soundings,
which Dr. Wollaston had not
seen,
that between the
Capes of Trafalgar and Spartel, which are twenty-two miles
apart,
and where the
deepest part, which
two hunch'ed and
is
the
Straits are shallowest,
on the side of Cape Spartel,
twent}"" fathoms.
7
It
is
only
therefore evi-
is
dent, that if water sinks in certain parts of the Mediter-
ranean,
in
consequence of the
since
it
it
of
its
S})ecitic
two hundred and twenty
gravity, to greater depths than
fathoms,
increase
can never flow out again into the Atlantic,
must be stopped by the submarine barrier which
crosses the shallowest part of the Sti'aits of Gibraltar."}; §
According to this reasoning,
431
His ..aequine not conclusive
all
the cavities, the hollows
and the valleys at the bottom of the
sea,
the trade-wiud region, where evaporation
and great, ought
to be salting
* "Tlie Mediterranean."
J
Lyel. » Priiioiplea of lieulogy,
up or
filling
especially in
is
+ One hundred and 3"4-5. ninth edition.
p. '
g425.
so constant
up with sixty,
brine.
Smyth.
L'ludon. 1853.
— CTRKENTS OF THE Is
SEA.
probable that such a process
it
1
79"
actually going on
is
?
No.
chapter -
to this reasoning, the water at the bottom § 432 American lakes ouo^ht great to be salt, for the ^'"" ® ^ would be rivers and the rains, it is admitted, bring salts from the the effects
According
of the
land continually and em})ty them into the
It
sea.
is sreat
American
admitted that the great lakes would from this cause
also
lakes
if
this rpii-
be
The Niagara
they had no sea drainage.
salt, if
river
passes these river salts from the upper lakes into Ontario,
and the
Now far
St.
Lawrence conveys them thence
the basins or bottoms of
all
to the sea.
these upper lakes are
below the top of the rock over which the Niagara
pitches
its
And, were the position assumed by
flood.
namely, that
this writer correct,
if
the water in any of
these lakes should, in consequence of
its specific
gravdty,
once sink below the level of the shoals in the rivers and straits
which connect them,
never could flow out again,
it
and consequently must remain there principle physically correct,
for ever*
—were
would not the water
bottom of the lakes gradually have received
this
at the
salt sufiicient,
duiing the countless ages that they have been sending off"
to the sea, to
make
this everlastingly pent-up
it
water
briny, or at least quite different in its constituents from
that of the surface at
the
?
We may
water, whether salt or fresh, of specific gi-avity
ever
presume that the water
bottom of every extensive and quiet sheet of
;
but that
is it
we have abundant proof
at the
bottom by reason
does not remain there for If so, the Niagara River
would be fed by Lake Erie only from that layer of water which
is
above the level of the top of the rock at the
* See paragi-aph quoted (p. 17S)
from "
Lyell's Principles of Geology."
soninf:
rect
180
THE PHYSICAL GEOGRArHY OF THE Consequentl}^, wherever
CHAPTKE Falls.
— VII
'-
is
no greater than
it
current as rapid as
it
tlie
at
is
breadth of that river
we should have a the moment of passing the leap. To see that such is
at the
is
SEA.
Falls,
make the not the way of Nature, we have but to look at any common mill pond when the water is running over the dam. top of the rock to
The current
in the
perceptible, for "
know
it is
pond
tliat feeds
the overflow
water runs deep."
still
to another
wherever above the Niagara Falls the water
And the cm'rent
are sure to
with the rate it is
cause
assumes as
it
§
Assump-
it
tioii
The -^Q
on
which
it
is
;
for,
deep, there
sluggish in comparison
approaches the Falls
;
and
sluggish in deep places, rapid in shallow ones, beis
The common
fed from below.
our canals teach us this 433
we
not such a skimming current as the geologist
would make, which runs from one lake
we
scarcely
is
Moreover,
" w^astes " in
fact.
reasoning of this celebrated geologist appears to
that when water, in confounded upon the assumption • i-
Sir
Lyeiis
sequence of
specific
its
gi-avity,
bottom of a cuiTent where
it
is
once sinks below the shallowest, there
is
no
ojiiiiioii
was
force
of traction
in
fluids,
nor any other power, which
founded.
can di'aw this heavy water up again. case,
we
If such
were the
could not have deep water immediately inside
of the bars which obstruct the passage of the great rivers Rate at wliich
Jnto the sca.
Thus the bar at the mouth of the
sippi, witli
ouly fifteen feet of water on
Jlississippi
travel? out
Missis-
••ill
tlie
bar of the
to travel out to sea at rates varying
it,
estimated
is
trom one hundred
to sea.
to §
434
twenty yards a year. In the place where that bar was
thousand yards nearer to
whether
it
were
fifteen
New
when
Orleans than
it
it
was one
now
is,
years ago or a century ago, with
—
—
CURRENTS OF THE
SEA.
1
only fifteen or sixteen feet of water on four or five times tliat depth. sively formed seaward
where
had placed
specific gravity
— fomed.
and
lifted
top of the bar at
its
mouth.
He
up from
it
and canned
it,
own bottom
its
chapthb
what dug up the out to
it
from the sur-
feet
makes
Indeed, Sir Charles liimself
?
stream to tear up
we have now
old,
more than a few
sea over a barrier not face
old,
1
bars were succes-
As new
from the
sediment which formed the
it,
H
^
majestic
this
depths far below the
to
describes the Mississippi
as a river having nearly a uniform breadth to the dis-
He makes
tance of two thousand miles from the sea.* it
cut a bed for itself out of the
which
soil,
is
heavier
than Admiral Smyth's deep sea water, to the depth of
more than two hundi-ed feetf below the top of the bar which obstructs its entrance into the sea. Could not the same power which scoops out this solid matter for the Mississippi,
terranean, Straits
draw the brine up from the pool and pass
it
out across
the
in the
ban'ier
Medi-
in
the
?
Tlie traction of locomotives on rail-roads,
of that traction,
is
well
and the
force
Now, have not
understood.
currents in the deep sea power derived from some such force
Suppose
?
this
under current from the Mediter-
ranean to extend one hundred and sixty fathoms down, so as to chafe the barrier across the Straits.
bottom of than
fifty
i
the
a pressure of more •
this current, then, there is
atmospheres.
Upon
Have we not
here a source of
* " Prom near its mouth at the Balize, a steamboat may ascend for two thousand miles with scarcely any percejjtible Jilference in the width of the river." Lr/ell, p.
263.
+ " The
Mississippi
is
continually shifting
plain, cuttincr frequently to tlie
depth of two hundred and
its
course in the great alluvial
depth of one hundred, and even sometimes
fifty feet."
Li/ell, p.
273.
to the
§
435
Force of traction on laii-roads.
^tep-sel J^^ve^"^'^
v°"'\^^^
ilenved *^''°'" ^ like force.
THE PHYSICAL GEOGRAPHY OF THE
182 CHAPTER
SE-\.
power that would be capable of dra^vang up, by almost an insensibly slow motion, water from almost any depth
At any
rate, it
traction, or friction, or
whatever
force,
below the level of their beds in shallow
—were
not so
?
appears that the effect of cui'rents by
the brine not
does extend far
Were
places.
drawn out again
—
it
would
it
be easy to prove that this indraught into the Mediterranean
by
taken, even during the period assigned
lias
Sir
Charles to the formation of the Delta of the Mississippi
— one
of the newest formations
whole basin of the
the
—
enough to
salt
Mediterranean
Admiral Smyth brought up bottom with of deep sea water (six hundred
no §
436
M\mv»\
with
up
fill
oiystals.
his briny
sample
and seventy fathoms), but
salt crystals.
The gallant admiral }jot,h
—
appearing to withhold his assent
from Dr. Wollaston in his conclusions as to this
Smyth's euggestioii
under current, and from the geologist in his inferences as to the effect of the barrier in the Straits
—
suggests the
probability that, in sounding for the heavy specimen of sea water, he struck a brine spring.
But the specimen,
according to analysis, was of sea water, and
how
did a
brine spring of sea water get under the sea but through
the process of evaporation on the surface, or witli a portion of its fresh §
437
If Sir
^^
we admit
Lyell, that
Charles
by parting
water in some other
the principle
way ?
assumed by Sir Charles
water from the r> and basins of oreat pools i
tlie
i.ycirs
sea can never ascend to cross the ridges which form these
he admit-
pools
hfirmoni.s
and wc are forced
Ire cone.'
particlc of
and
basins, then the
Ipso facto,
harmonies of the sea are gone,
to conclude they never existed.
Every
Water that sinks below a submarine ridge
is,
by his reasoning, stricken from the channels
CURRENTS OF THE
for ever motionless chapter VII. „
become thenceforward
of circulation, to
183
SEA.
.
The consequence would be " cold obstruction the depths of the sea, and a system of circulation be-
matter. in
tween
different seas of the waters only that float
the shoalest reefs and barriers. existence of in
—
any such ''
I
any such imperfect
the theoretical proofs
— —
do not believe in the
mechanism, or
terrestrial
To
failures of desigTi. ®
above
my
mind, the proofs ^
'' _
Authm-s opinion.
^
the proofs derived exclusively
from reason and analogy
are as clear in favour of this
under current from the Mediten-anean as they were in favour of the existence of Leverrier's planet before
was
it
seen through the telescope at Berlin.
Now
suppose, as Sir Charles Lyell maintains, that none
of these vast quantities of salt
which
would not be
difficult to
438
this surface cm-rent
takes into the Mediterranean find their It
§
show, even
way
out again.
to the satisfaction
of that eminent geologist, that this indraught conveys
away from the Atlantic faster than all the /res/i- water Now, I'ivers empty ^'' fresh supplies of salt into the ocean. salt
^ ^
_
besides this dj'ain, vast quantities of salts are extracted
from sea water for madi'epores, coral
and marl beds
;
perfectly sound this
reefs,
and by such reasoning as and good, we
imder current, or
else
we
and becoming
less
and
this
-^
we
this,
must be
less briny.
examining features of ® the physical ^ its conditions,
shell banks,
which
is
are led to look for
...
—By
sea,'' '
losing
sheiis,
carefully § 439
and study^
warm
currents .
volumes of overheated water, probably exceeding in 1
thefom.ii-
its
that have their genesis in this ocean, and that carry from it
fiomseawaler for
are forced to the very un-
The Currents of the Indian Ocean. ing
is
extracted
establish the existence of
[ihilosophical conclusion that the sea salts,
sait
_
Plates VIII and IX.
wanncurrents in
Indian Ocean.
THE PHYSICAL GEOGRAPHY OF THE
184 CHAPTER
—
'•
Gvilf
times
Stream from
which
tliat
discharged by the
is
fountains (Plate VI.).
its
Ocean
Tlie Atlantic
440
§ Facts
many
quantity
open at the north, but tropical
is
bound the Indian Ocean
countries
SEA.
that
in
direction.
s'.iow tlieir
e.xisteuce.
The waters
of this ocean are hotter than those of the is much we might, without observa-
Caribbean Sea, and the evaporating force there'
That
greater.
from the fact of a higher temperature and a
tion, infer
Mozambique current.
§
gi-eater
amount of
shores.'
These two
seem, to
show that
Straits
it
One
of
them
called at the
Another of these currents makes
would
warm water have
currents of
lai-ge
weU-kuown Mozambique current, Good Hope the LaguUas current.
the
is
Gape
of
escape through
its
by other warm
the Straits of Malacca, and, beinsr joined '^
streams from the Java and China Seas, flows out into
through tiie
neighbouring
the
taken together, tend,
current e-^cipes
on
precipitation facts,
their ° crenesis in the Indian Ocean.
441
Another
greater
it is
_,
_
^
tlic Pacific,
like another
.
.
Gulf Stream, between the Philip-
of Malacca
Thence
pines and the shores of Asia.
it
attempts the
great circle route^for the Aleutian Islands, tempering mates, and losing itself in the sea on
its
cli-
route toward the
north-west coast of America. §
Between the physical features of
442
I'ointsof
this current
and the
Gulf Stream of the Atlantic there are several points of
resein-
hiancebetwcen tliis
rcsemblance.
current and the
and Cuba
iif
Sumatra and Malacca correspond
to Florida
Borneo to the Bahammas, with the Old Provi-
;
dence Channel to the south, and the Florida pass to the
Stiram.
west.
The
coasts of
China answer
States, the Philippines to the
to
Newfoundland.
here with
tliis
§ 210.
«
g
United
Bermudas, the Japan Islands
As with
the
China current, »
to those of the
Gulf Stream, so also
tliere
202.
is
'
a counter-current
§ 53.
CURRENTS OF THE of cold water between
and the
it
185
SEA.
The
shore.
the Asiatic coast correspond with those of
climates of chapter
America along
and those of Columbia, Washington, and
the Atlantic,
Vancouver, are duplicates of those of Western Europe
and the British Islands
the climate of California (State)
;
resembling that of Spain regions of deserts
its
Lower
California reminding one of Africa, with parallels, &c.
like the
Pacific,
North
Atlantic,
warm
with mists waters go, ° and streaked with lightning. The Aleutian
enveloped, where these '
the sandy plains and rainless
between the same
Moreover, the North is
;
§
443
Fogs and mists.
_
and
fogs,
Islands are almost as renowned for fogs and mists as are
the
of Newfoundland.
Grand Banks
A
sui'tace
current flows north through Behring's Strait
into the Arctic Sea
:
§
444
is Current through sur- Beiinngs
but in the Atlantic the current
from, not into the Arctic Sea
:
it
flows south on the
strait.
face,
north below
;
Behring's Strait being too sliallow to
admit of mighty under cm-rents, or to permit the introduction from the polar basin of any large icebergs into the Pacific.
Behring's Strait, in geographical position, answers to Davis's
Strait
in
the Atlantic
; '
and Alaska, wdth '
Aleutian chain of islands, to Greenland. there beinor ® to the east of Alaska, as there
its
445
Behiins's strait
But instead of to the east
is
§
with tho^f
ofDaviss _
of Greenland, an escape into the polar basin for these
warm
waters of the
turns them
Pacific, a shore-line intervenes,
down through a
sort of
cool
water upon the
marked.
Being
The
effect of this
They body of
littoral climate of California is
cool,
it
gives
and
North Sea along the
western coast of the continent toward Mexico.
appear here as a cold current.
freshness
and
currents
compared
very
and strength
strait.
1
THE PHYSICAL GEOGRAPHY OF THE
S6
summer
CHAPTER to the sea-breeze of that coast in
—
'-
" coolinor
is
most
These contrasts show
446
§
ijiffeience
sea-breeze"
SEA.
when
time,
the
crratefuL
principal points of resem-
tlie
blance and of difference between the currents and aque-
between currents
The
qus circulation in the two oceans.
ice-bearing ° cur-
of Xorth _
Atlantic
rcnts of thc
North Atlantic are not repeated
as to
volume
and North Pacific
North
the
in
Pacific,
for there
bergs like the frozen ocean and
Okotsk and Kamschatka
no nursery for
is
its
447
§
Current of
warm
water from the Indian Ocean.
is,
ice-
seas of
and not the frozen seas
alone,
North
of the Arctic, cradle the icebergs for the
There
The
arms.
Pacific.
at times at least, another current of
wami
way
south
water from the Indian Ocean.
midwav between
It finds its
Africa and Australia, and appears to
*^ ,
.
,
.
strewed with
lose itsclf in a sort of Sargasso Sea, thinly
Tlie whales also^give indications of
patches of w^eed.
Nor need we be
surprised at such a vast flow of
it.
warm
water as these three cun-ents indicate fi-om the Indian Ocean,
when we
recollect that this ocean^ is land-locked
on the north, and that the temperature of is
waters
There must, therefore, be immense volumes of water
448
§
its
frequently as high as 90° Fahr.
flowing into the Indian Ocean to supply the waste created
by
these
warm
cuiTcnts,
and
tlie fifteen
or twenty feet of
water that observations^ tell us are yearly carried this §
449
Ice bearliiu
cur-
'«"t'^
On ^|jg
off
from
ocean by evaporation. either side of this
intcr-tropical 1
between
Afi'ica
found wending
parts r
and its
warm
cun-ent that escapes from
Indian
of the
way from
Ocean,* midw^ay >
and
aqueous equilibrium in that part of the world. i'bie IX.
2
§ 439.
3
is
the Antarctic regions with
supplies of cold water to modify climates,
>
.J
an ice-bearing current'
Australia,
§ 33.
*
i
U7.
«
restore the
The
pi^te [X.
cur-
CURRENTS OF THE up
rent that flows
to the
SEA.
west of this
]
87
vreecly sea is the chapter
—
"vn.
Its bergs occasionally interfere
greatest ice-bearer. vessels
bound
by the new route
to Australia
The former sometimes
the other seldom.
40° south.
far north as the parallel of
;
'-
with
those of
drifts its ice as
The Gulf Stream
seldom permits them to get so near the equator as that in the
mg
North Atlantic, but 1
•
have known the ice-bear-
I
f
1
South Atlantic to convey of 37° south latitude.
TT
r^
•
Cape Horn mto the
current which passes east oi
Nearest approach
oncebfiRs
bergs as far as the parallel
its
This
is
the nearest approach of
icebergs to the equator.
These currents which run out from the inter-tropicai
—
basin of that immense sea
Indian Ocean
—
are
active
They convey along immense volumes of water containing vast quantities of salt, and we know that sea currents.
water enough to convey back equal quantities of
and
salt to
must flow of the
keep up into or
same sea
upon the
svipplies for the
return
450
^"''"^
Ocean currents.
salt,
outgoing currents,
the inter- tropical regions
to
therefore,
;
if
observations were silent
reason would
subject,
§
us
teach
currents here that keep in motion
to look for
immense volumes of
water.
The Currents of the
Pacific.
drawn^ between the China or
—The
contrast has been
Gulf Stream" of the North
Pacific,
and the Gulf Stream of the North
Atlantic.
The
course of the China Stream has never been satisfactorily -
§
451
cunenta of the
./»
-r»
"
1
traced out.
.
There
s
is
Mexico, a southwardly
Pacific.
chma. stream.
along the coast of California and
movement
of waters, as there
is
along the west coast of Africa toward the Cape de Verd Islands.
In the open space west of this southwardly >
S 442.
2
Plate IX,
set
along
§
452
THE PHYSICAL GEOGEAPHY OF THE
18S
famous Sargasso
CHAPTEK the African coast, there is the VII.
.
is
SEA. Sea,^
which
.
the general receptacle of the drift-wood and sea-weed So, in like manner, to the west
Pacific
of the Atlantic.
Sargasso
California of this other southwardly
from
the pool into
set, lies
which the drift-wood and sea-weed of the North
Pacific
are generally gathered, but in small quantities. §
The natives of the Aleutian
453
Islands,
where no
trees
grow, depend upon the drift-wood cast ashore there for the timber used in the construction of their boats,
all
and household
fisliing-tacle,
Among
gear.
this
timber,
the camphor-tree, and other woods of China and Japan, Evidence regarding
.^^q ^^^[^
the China
additional evidence
^q
\)q
Stream. _
In this fact
often recogniscd. ^
we have
touching ^ this China Stream, as to " The Japanese," says known. at best is _
_
which'' but little
Lieutenant Bent,* in a paper read before the American Geogi'aphical Society, January, 1856, "are well aware of its existence,
and have given
or Black Stream, which
deep blue colour of
its
is
it
the
name
of
'
Kuro-Siwo,'
undoubtedly derived from
tlie
when compared with that From this we may infer" that the
water,
of the adjacent ocean."
blue waters of this China Stream also contain more salt
than the neighbouring waters of the §
454
c..id cur-
The Cold Current of Okotsk. ter to the
rent of
Dkutsk.
is found"*
inff
coast.
Inshore
of,
but coun-
China current, along the eastern shores of Asia, *= '
a streak, or layer, or cmrent of cold water answer-
to that
strono-
—
sea.
between the Gidf Stream and the American
This current, like
enough
navio-ation
;
its
fellow in the Atlantic,
is
not
at all times sensibly to affect the course of
but, like that in the Atlantic,
it
is
the nur-
* Lieutenant Bent was in the Japan Expedition with Commodore Perry, and used the opportunities thus afforded to study tlie phenomena of this stream. >
Plate IX.
'
§
45L
»
§ 4.
§ 442.
1
CURRENTS OF THE most valuable
eery' of
The
fisheries.
are quite as extensive as those of
189
SEA.
Japan
of
fisheries
chapter
—
Newfoundland, and the
people of each countiy are indebted for their valuable
'-
of
j^pa^
§
455
supplies of excellent fish to the cold waters which the
currents of the sea bring
Humboldt's Current. but
little
down
Among
understood.
to their shores.
—The
cuirents of the Pacific are those about which most
is
Humboldt s
known is the Humboldt Current of Peini, great man whose name it bears was the first to
thought to be
which the discover.
It
has been traced on Plate IX. according to
the best information
This current
ject.
—
defective at best
is
felt
The Andes, with
delightful
—upon
tlie
sub-
the equator, miti-
far as
as
gating the rainless climate of Peru as it
it
goes,
and making
their snow-caps, on one
of the naiTOW Pacific slopes of this inter-tropical
side
republic,
and the current from the Antarctic regions on the
make
other,
world
;
for,
its
climate one of the most remarkable in the
though torrid as to
latitude, it is
temperature that cloth clothes are seldom
dming any time
such as to
felt as
oppressive
of the year, especially after nightfall
Between Humboldt's Current and the great equatorial flow there
is
an area which
may
be called the " desolate
was observed that this part of the ocean was why, visited by the whale, either sperm or right
region."* i-arely it
It
;
did
not appear
;
but observations asserted the
fact.
Formerly, this part of the ocean was seldom whitened by the sails of a ship, or enlivened
by
the presence of man.
Neither the industrial pursuits of the sea nor the high-
ways
of
commerce
called
him
into
it.
Now
and then a
roving cruiser or an enterprising whaleman passed that
way
cunent.
;
but to
all else it
'
§ 70.
was an unfrequented part of '
Plate IX.
tlie
§
456
?]g*„,,.,.,
^^s'°"-'
1
THE PHYSICAL GEOGRAPHY OF THE
90
and
CHAPTER ocean,
—
and
'-
so remained until the gold-fields of Australia
guano islands of Peru made
tlie
bound from Australia
All vessels Sea-buds fc/jow
SEA.
^.
it
a tlioroughfare.
South America now
to
pass throusfh ^ it, and in the journals of some of them it is n i-n described as a region almost void of the sio-^s of life in
.„,.
.
both sea and
air.
where there
is
In the South Pacific Ocean especiaEy,
such a wide expanse of water, sea-birds
often exhibit a companionship with a vessel, and
company with
follow and keep
Even
weeks together.
for
it
those kinds, as the albatross
and Cape pigeon, that delight Cape Horn and
summer
But not this
In
rp^^^
regMn
accompany
clears Australia sea-bu'ds that ioin the ship r as she said, follow
is
Even the
ap])ear.
her to this region, and then disof the stormy-petrel ceases to
chii-p
be heard here, and the sea baiTen of
457
A warm current discovered
f.omtiie
vessels into the per-
of the tropics. ''
will, it
§
stormy regions of
in the
the inhospitable climates of the Antarctic
regions, not unfrequently
petual
will
through storm and calm
"
moving
itself is
said to be singularly
creatures that have
life."
I have, I believe, discovered the existence of a
cmTcnt
warm mid-
regions of the Pacific, froui the inter-tropical * °
-way between the American coast and the shore-lines of
This region affords an immense sm*face for
Australia.
inter-tropical re-
pions of tiiePadtic.
No
evaporation.
m
,
rain,
,
except
the evaporation south-east
rivers
empty
the " Equatorial is
all
into
it
;
the annual faU of
Doldrums,
>)
•
is
Ti
small,
that both the north-east
trade-winds can take up and carry
1
and
and the off.
I
have marked on Plate IX. the direction of the supposed
warm water
current which conducts these overheated and
briny waters from the tropics in mid ocean to the extratropical regions
where precipitation
is
in excess.
Here,
being cooled, and agitated, and mixed up with waters that
are
less
salt,
these
over-heated
and
over-salted
— S
CURRENTS OF THE waters from
tlie
tropics
may
SEA.
1
9
1
be replenished and restored chapteh
to their rounds in the wonderfid system of oceanic circulatioiL
There are also about the equator in this ocean some curious cm-rents which
do not understand, and as to
I
§
45
Cunous currents,
which observations are not
sufficient
yet to aflbrd the
not under stood.
There are
proper explanation or description.
many
of
On
them, some of which, at times, run with great force.
a voyage from the Society to the Sandwich Islands, I
encountered one running at the rate of ninety-six miles
a day.
And what
else
should
we
expect in this ocean but a
the system of cm'rents and counter-currents apparently A •'
''
•••
most
uncei-tain
The
and com})licated ?
the Indian Ocean may, in the view
be considered as one sheet of water.
we
Pacific
Ocean and
§
459
compiicateu system of currents
are about to take,
This sheet of water
covers an area quite equal in extent to one half of that
embraced by the whole sm'face of the earth ing to Alexander Keith Johnston, it
in the
total
new
annual
who
and, accord-
;
has thus stated
edition of his splendid Physical Atlas, the
fall
of rain on the earth's sm-face
is
one hun-
dred and eighty-six thousand, two hundi'ed and forty
Not
cubic imperial miles.
less
than three-foui'ths of the
vapour which makes this rain comes from waters
;
ninety-three
thousand,
taken up from
two hundred and water which this expanse.
down
waste of
is
it
at another,
and that that much,
fifty-five cubic miles as the
is
at
again as vapour, this would give
daily lifted It
i. e.,
one hundi-ed and twenty cubic
miles of rain falls upon this sea, least, is
tliis
but supposing that only half of this quantity,
quantity of
up and poured back again into
taken up at one place and rained
and
in
tliis
place, therefore,
we have
^f^Jj^'"""''
THE PHYSICAL GEOGRAPHY OF THE
192
CHAPTER agencies for multitudes of paiiial
—
.
in their set
all,
and
SEA.
conflicting current^
and strength, apparently as uncertain
as
the winds. §
The
460
suppi«i:a case.
better to appreciate the operation of such agencies
producing o currents in the sea, now here, now there, first this way, and then that, let us, by way of illusjj^
X
tration,
imagine a
two hundred and
district of
fifty-five
square miles in extent to be set apart, in the midst of the Pacific Ocean, as the scene of operations for one day.
We
must now conceive a machine capable of pumping water to the depth
up, in the twenty-four hours, all the
The machine must not only
of one mile in this district.
pump up and but
it
bear
off"
must discharge
creating currents that effects that
immense quantity of water,
again into the sea on the same
it
some other
day, but at
this
Now
place.
here
equivalent in
is
would be produced by bailing
four hours,
two hundred and
is
a force for
its results
to the
up, in tAventy-
cubic
fifty-five
miles
of
water from one part of the Pacific Ocean, and emptying it
out again upon anotlier part.
The cuiTcnts that
would be created by such an operation would overwhelm navigation,
and desolate the sea
;
and, happily for the
Atiiio^i h&-
liuman
agency,
actually does perform every day, on the average, all this
race,
the
great
lifting up, transporting,
atmospherical
and
letting
machine which
down
upon
of water
the face of the grand ocean, does not confine itself to
an area of two hundred and to
fifty-five
square miles, but
an area three lumdred thousand times as gi-eat
nevertheless,
the same
quantity of water
is
;
yet,
kept in
motion, and the currents, in the aggregate, transport
much water
to restore the equilibrium as they
a.s
would
CURRENTS OF THE have to do were oiu-
SEA.
93
]
the disturbance to take place upon cnArTEh
all
hypothetical area of one mile deep over the space of
two hundred and
we come
Now, when
square miles.
fifty-five
to recollect that evaporation
is
that
lifting up,
the winds are transporting, and that the clouds are letting
down every day reminded that
and by
actually such a
it
done by
is
body of water, we are
little
and
little
at a place,
breadths at a time, not by parallelopipedons
hair's
one mile thick
—
that the evaporation
is
most rapid and
the rains most copious, not always at the same place,
but
now
here,
now
there.
We
thus see actually existing
a force perhaps quite sufficient to give
in nature
—
conciudvations.
which mariners
to just such a system of currents as that find in the Pacific
rise
currents which appear to rise in
mid
ocean, run at unequal rates, sometimes east, sometimes
west, but
which always
lose themselves
where they
rise,
namely, in mid ocean.
Under Currents. U.
S.
schooner
"
—Lieutenant
J.
C.
Taney," and Lieutenant
Walsh, in the S.
P.
Lee, in
§
4g1
cnder currents.
the U.
S.
brig " Dolphin," both, while they were carrying
on a sj^stem of observations in connection with the
AND Current Charts, had
their attention
Wind
directed to
the subject of submarine currents.
They made some subject.
A
block of
by means of a
interesting
experiments upon the
wood was loaded
to sinking, and,
fishing-line or a bit of twine, let
down
to
the depth of one hundi-ed or five himdred fathoms, at the will of
tlie
experimenter.
just sufficient to
was then
A
small barrel as a
keep the block from sinking
tied to the line,
and the whole
I'oat.
13
let
float,
farther,
go from the
§
462
Experi-
THE PHYSICAL GEOGRAPHY OF THE
194 c
iAPTFR
To use
their
" It
expressions,
o^v^l
SEA.
was
woiiderfu],
VII.
indeed, to see this barrega
§463 Surprising lesiilt.
sea,
and surface
move
against wind, and
off,
current, at the rate of over one
knot an
hour, as was generally the case, and on one occasion as
much
The men
as 1 1 knots.
exclamations of surprise, for
in the
it
boat could not repress
really appeared as if
some
monster of the deep had hold of the weight below, and
was walking amazed §
4G4
F.xperi-
ments
off
with
it."*
Both
officers
and men were
at the sight.
The experiments in deep-sea soundings have also thrown light upon the subject of under currents. There i=
much
in
deep-sea simndings.
rcasou to belicve that they exist in
or almost all parts
all,
of the deep sea, for never in any instance yet has the deep-sea line ceased to run out, even after the
plummet
had reached the bottom. §
4G5
Sounding-
If the line be held fast in the boat,
showing,
when two
or three miles of
it it
invariably parts, are out, that the
lines broicen.
uuder-cmTcnts are sweeping against the bight of
what seamen
call
a siuigging force,
that no
it
with
sounding
twine has yet proved strong enough to withstand. §
466
Lieutenant
J,
P.
Parker of the United States
Lieuten-
" Cougress,"
er'sexperiment.
the coast of South America. _
frigate
attempted, in 1852, a deep-sea sounding _
ofl
...
He was
_
engaged with the
experiment eight or nine hours, during which time a line nearly ten miles long was paid out.
Night coming
on,
he had to part the line (which he did simply by attempting to haul
it
in)
and return on board.
Examination
proved that the ocean there, instead of being over ten miles in depth,
was not over
three,
and that the
line
was
swept out by the force of one or more under cm-renta * Lieuloiutnl Walsli.
CURRENTS OF THE But
in
what
195
SEA.
direction tliese currents were running
is
not chapter VII.
known. ,
It
may,
without doing any violence to
tlierefore,
tlie §
rules of philosopliical investigation, be conjectured, that
equihbnum
the 1
or less extent,
If
may
we
r>
system of cm-rents and counter-
down
it
briumof
surface.
and the
tides,
may
such as those that lay
garding equili-
this
except the
preserved, to a gi-eater
is
•
1
by
and below the
currents at
fiea,
of all the seas 1
4G7
conjec-
partial currents of the
be created by the wind,
we
Rule laid down, that ocean currsnts
as a rule^ that all the cmTents of the
ows
their ori-
ocean owe their origin to the difference of specific gravity
ference of
between sea water at one place and sea water at another
gravity of
wherever there
for
owing
to
such a difference, whether
is
it
;
be
difference of temperature or to difference of
saltness, &c., it is
at'diffnient
^'*"'"
a difference that distm'bs equilibrium,
and currents are the consequence.
The heavier water
goes toward the lighter, and the lighter whence the heavier
comes
for
;
and standing
two
same
at the
differing in specific gravity,'
fluids
level,
can no more balance each
other than unequal weights in
opposite
It
scales.
is
immaterial, as before stated, whether this difference of specific
gravity be caused by temperatm-e, by the matter
held in solution, or
by any other thing
;
the effect
is
the
same, namely, a cm-rent.
That the
it
holds in solution the same
sea, in all pai-ts,
kind of solid matter
waters in this place, where ^ never rains, are not Salter than the strongest brine :
'
that
its
'
§
468
^^°°^^
thatwa ^eis of ti.e
;
sea aie
and that in another
place,
where the rain
they are not entirely without
salt,
may
is
incessant,
be taken as evi-
dence in proof of a system of currents or of circulation in the sea, by which
its
^
waters are shaken
§ 31.
«
§ So.
u^)
and kept
shaken tip and mixe34
pmofafforded by Arctic Toyajjers.
direction of Davis' Straits, have afforded
^1^
'
observations,^ ^proof positive ^
as
to
tlie fact
source for supplying the Polar Seas with
by 'J
their
us,
of this other
They
salt.
tell
us of an under current setting from the Atlantic toward
They
the Polar basin.
high up in
tend far tearing
their
down into the depths of the ocean, ripping and way with terrific force and awful violence
sfidsiiip-
man Griffin.
way
ice,
or against a surface current, on
into the Polar basin.
Passed Midshipman
535
which ex-
ba.ses of
tlieir
through the surface
§
describe huge icebergs, with tops
and of course the
tlie air,
S. P.
Griffin,
who commanded
the
after O expedition I o Rescue in the American searching gjj. John Franklin, informs me that, on one occasion the
\)Y\ct
two vessels were endeavouring, when in Baffin's Bay, to warp up to the northward against a strong surface current,
which of course was setting
Iceberg
while SO engaged, an iceberg, with
against
the watcr.
tlie
" drifting o
Came
current.
to the south; its
top
from the up" i
many
south,
and that feet
above
and passed
_
by them "like a
shot."
Although they were stemming
a surface current against both the berg and themselves,
such was the force and velocity of it
tlie
under current, that
carried the berg to the northward faster than the crew
could warp the vessel against a surface but counter current. §
536
Captain Duncan, master of the
Dundee, rative
:
says, at
—
* Arctic Regions Sliip
;
English
page 76 of his interesting
Voyage
to Davis' Straits,
Duudee, 1S26, 1827. »
S 47S.
whale-ship little
nar-
by Dorea Duncan, Master of the
—
^
THE SALTS OF THK " Dec.
ISfh
from
was
It
[1826].
immense icebergs working
and not one drop of water
us,
behold the chaptk?
to
aw-ful
way
their
227
SEA.
to the north-east
they were
to be seen;
working themselves right through the middle of the
And
again, at page 92, &c.
ice."
—
'-
Duma,.^ onlc'e'^'^'''
:
"Feb. 2Sd. Latitude 68° 87' north, longitude about 63° west. "
The dreadful apprehensions that
us yester-
assailed
coiitinued
day, by the near approach of the iceberg, were this day
most awfully
came it
About three P.M. the iceberg and in less than one minute
verified.
in contact with our floe,
broke the
We
ice.
shore; the floe
were frozen in quite
was shivered
to
close to the
pieces for several miles,
causing an explosion like an earthquake, or one hundred
heavy ordnance
pieces of iceberg,
fired at the
same moment.
with awful but majestic grandeur
(in
The
height and
dimensions resembling a vast raoimtain) came almost up to our stern,
and every one expected
would have run
it
over the ship "
The
iceberg, as before
observed,
came up very near
to the stern of our ship; the intermediate space
the berg ice,
the a
and the
was
vessel
filled
between
with heavy masses of
which, though they had been previously broken
immense
compact body by
its
mass of
ice,
The berg was
pressure.
at the rate of about four knots,
by
were again formed into
weight of the berg,
and by
was pushing the ship before
its force
it,
as
it
drifting
on the
appeared,
to inevitable destruction.
"Feb.
away
24ith.
The iceberg
still
in sight,
but
driving
fast to the north-east.
"Feb
25th.
The
iceberg; that so latelv
threatened
oiu*
continue.!
THE PHYSICAL GEOGRAPHY OF THE
228
had driven completely out of sight
CHAPTER destiniction
—
'-
§
to the
north-east from us."
Now,
537
Author's
SEA.
q[jjq
opinion.
then, whence, unless from the difference of spe-
gravity due sea water of different degrees of saltness o o »'
and temperature, can we derive a motive power with tremendous masses of
force sufficient to give such
a velocity §
TrniiiiM-atiire
What
038
such
the temperatm-e of this under cm-rent?
Be
?
is
that what
ice
it
may,
it is
probably above the freezing point
of
under cur- ()f
Suppose
sca watcr.
Break through
to be at 82°,
it
the ice in the northern seas, and the temperature of the Tempera-
Water
surface
always
is
28''
;
at least Lieutenant
tnve of surface water.
Haven
so found
it
and
in his long imprisonment,
be supposed that, as
was with him,
it
so
it
it
De may
generally
is.
Assuming, then, the water of the surface current which rims out with the is
ice to
be
all
at 28°,
we
observe that
it
not unreasonable to suppose that the water of the under
current,
inasmuch as
fore
from warmer
if it
be not so
acrain,
must
it
comes from the south, and there-
latitudes, is
cold, its
probably not so cold; and
temperature, before
be reduced to 28°, or
it
comes out
whatever be the aver-
age temperature of the outer but surface current. Temjieia-
Kane fouud
Arrtic
Occau* as high as 36°.
Dr.
the temperature of the open sea in the Arctic
Can water flow
in the depths
below from the mild climate of the temperate zones to the sevei'e climate of the frigid zones without falling below
36°?
To what,
in
the depths of the sea, can a
current of large volume impart §
639
Moreover,
if it
gested, that there
its
warm
heat?
be true, as some philosophers have sugis
in the
depths of the ocean a floor or
plane from the equator to the poles along which the water
THE SALTS OF THE is
of
tlie
may be
same temperature
asked, Should
which
side of
the way, then the question chaptes
all
floor,
—
IX.
we not have
ocean a sort of isothermal
2 29
SEA.
in the depths of the
as
were, on the upper
it
'-
floor in the
the changes of temperature are due to
all
agents acting from above, and on the lower side of which, the changes,
if
any, are due to agents acting from below?
This under Polar current water, then, as top,
and
is
to the
it rises
brought to the surface by the agitation of the
§
540
c'-'"sp "f
watersky of tlie
sea in the Arctic Regions, gives out
surplus heat and
its
Polar
warms
the atmosphere tliere
warm under
current water
till
is
the temperature of this
lowered to the requisite
Hence the water-
degree for going out on the surface.
sky of those
And
regions.
regions.
the heat that
from
loses in falling
it
temperatm'e, be that what
it
may,
till it
its
normal
reaches the tem-
§
541
cause of modifica-
perature of 28°,
is
so
much
caloric set free in the Polar
Regions, to temper the air and mitigate the climate there,
Now,
is
tionof Polar climate.
not this one of those modihcations of climate
which may be
fairly traced
back to the
ness of the sea in giving energy to
Moreover,
if
its
effect of the salt-
circulation?
there be a deep sea in the Polar basin,
which serves as a receptacle
for the
waters brought into
§
542
Kasyto imaRine
it
by
this
under current, which, because
comes from
it
... imagme why
there
why
Lieu-
toward the equatorial regions, comes from a milder climate,
and
IS
therefore warmer,
might be an open sea
we can
easily
in the Polar
Regions
;
De Haven,
f
and why both he and Captain Penny, of one of the
)r it
;
was directed
there
might be an open sea in
tenant
in his instructionsj'
«hy
Poiar
to look
English searching vessels, and afterward Dr. Kane, found it tliere.
And
in accounting for this polynia,
"
§482.
we
see that
its §
543
THE PHYSICAL GEOGRAPHY OF THE
230 CHAPTER existence
—
is
not only consistent with
SEA.
hypothesis with
tlie
IX.
which we circulation,
Jits'ofsea
at least,
ty^uici'-^
salts
tulation of its
waters
if
but that
it
may
be ascribed,
m
a great degree
not wholly, to the effect produced by the
of the sea
upon the mobility and
circulation of its
,
WaXCrS.
Here, then,
544
§
touching a perfect sj'stem of oceanic
set out,
p.ioduced
an
is
which the sea performs in the
office
coneiud-
ecouomy of the universe by
marks.
whicli
And
viitue of
could not perform were
it
its
saltness,
its
waters altogether
and
fresh.^
have a clew placed in their hands
tlius philosopliers
Avhich will probably guide
them
to one of the
many
bid-
den reasons that are embraced in the time answer to the question, " § Sea
siieiis
Lime em-
Why
Sea Shells.
545
common
pic.ye.i in
rivers,
nnation.
of
it,
is
the sea salt?"
—We
find in sea
Lime
salt.
and emptied coral islauds
beds, shell -banks,
is
by the
rains
''
and the
in vast quantities into the ocean.
and
and
coi-al
Out
reefs of great extent, marl-
infusorial deposits of
nitude, have been constructed deep.
water other matter besides
dissolved
enormous mag-
by the inhabitants of the
These creatures are endowed with the power of
secreting, apparently for their
own
purposes only, solid
But
matter, which the waters of the sea hold in solution. this
power was given
to
them
the part assigned them in the Office of
.7
otthe df-ep.
546
fulfil
of the universe.
allotted the important
of assistiucr crivinar circulation to the ocean, of & in o 6 helping to regulate the climates of the earth, and of preofiicc .
serving the purity of the §
they also might
economy
For to them, probably, has been
the iniiabitants
tliat
The better
to
fluence cuirents
sea.
comprehend how such creatures may and
be perfectly at rest
in-
climates, let us suppose the ocean to ;
that througliout,
it
is
in a state of
;
THE SALTS OF THE complete equilibrium
231
SEA.
that, ^vith the exception of those chapteb
;
tenants of the deep which have the power of extracting Supposl-
from in
the solid matter held in solution, there
it
is
no agent
nature capable of disturbing that equilibrium
that
all
these
have suspended their
fish, &c.,
tton.
and
;
secretions, in
order that this state of a perfect aqueous equilibrium and repose throughout the sea might be attained.
In
this state of tilings
perfect equilibrium ^ *
suppose,
—
commences
a
—
the waters of
mollusc or coralline,
sincjle
°
we
will
§
547
Effect of
the opera-
secretions,
liis
sea being in
tlie
and abstracts from the
tionsofa single
sea water^ solid matter for his
In that
cell.
this
act,
coiaiiine.
animal has destroyed the equilibrium of the whole ocean for the
which
matter has been abstracted
this solid
Having
of that portion of water from
specific gravity
lost
a portion of
specifically lighter
than
its
it
altered.
is
become
solid contents, it has
was before
;
it
must, therefore,
give place to the pressure which the heavier water exerts to
push
it
aside
and
to
se([uently travel about
occupy
other parts of the ocean until ter is returned to
and
it,
its place,
and
must con-
it
and mingle with the waters of the its
proportion of solid mat-
until it attains the exact degi'ee
of specific gTavity due sea water generally.
How much plants
solid
matter does the whole host of marine
and animals abstract from sea water daily
a thousand pounds, or a thousand millions of tons .
one can say. r>ii
oi the
power
of the ocean.
?
No ,
.
•
11
^
And
this
power
is
loi-oniution.
•in
derived from the salts
marine animals, that of themselves scarcely
and other posse.ss
the
Yet they have power to put the ^
§493.
§
548
it soiid matter ab.
But, whatever be its weight, it is so much n T gravity applied to the dynamical forces
oi
of the sea, through the agency of sea shells
power of
Is
?
stracteci
fi'om sea
tymariie animals.
THE PHYSICAL GEOGRAPHY OF THE
232 CHAPTER
whole sea in motion, from the equator
SEA.
to the poles,
and
from top to bottom. §
Those powerful and strange equatorial currents^ which
549
Probable cause of
naviorators tell us they encounter in the Pacific Ocean, to °
currents in
what
"^
are
Coming from
they due?
unknown,
sources
tat- Pacitic.
they are
lost in the
no doubt,
some
to
They
midst of the ocean.
are due,
extent, to the effects of precipitation
and evaporation, and the change of heat produced thereby.
But we have yet
to inquire
how
far
may
they
be due to
the derangement of equilibrium arising from the change of specific gravity caused
by the
secretions of the myriads
of marine animals that are continually at
work
in those
These abstract from sea water solid
parts of the ocean.
matter enough to build continents of
And
also
we have
to inquire as to the extent to which equilibrium in the
sea
distm-bed
is
by the
salts
which evaporation leaves
behind.
Thus,
550
§
when we view, wc
consider the salts of the sea in one
winds and the marine animals
Principles
point of
of antago-
^
nistic
operating upon the waters, and, in cei-tain parts of the
See the
ocean, deriving from the solid contents of the
same those
very principles of antagonistic forces which hold the earth in its orbit, §
551
Dynamical
and preserve the harmonies of the imiverse.
In another point of view, we see the sea breeze and the sca
sliell,
in
performing their appointed
offices,
acting
forces.
so as to give rise to a reciprocating
and thus they impart
to tlie ocean
motion in the waters; dynamical forces also
for its circulation. §
The
552 sea
The fresli
sea breeze plays
upon the
surface
watcr into vapour, and leaves the
;
it
converts only
solid
matter be-
bieeze.
hind.
The
surface water thus
^
becomes
§458,
specifically heavier,
^
THE SALTS OF THE and
On
sinks.
the other hand, the
233
SEA. little
marine architect
chapter
—
below, as he works upon his coral edifice at the bottom,
abstracts from the water there a portion of its solid con- anacoun tents
therefore becomes specifically lighter,
it
;
and up
it
goes, ascending to the top Avith increased velocity, to take
the place of the descending column, which, of the winds, has been sent
and materials
for the
busy
down
by the action
loaded with fresh food
mason
little
in the depths
below. Seeing, then, that the inhabitants of the sea, with their
powers of secretion, are competent to exercise at least
§
552
Position
assigned
some degree of influence
in disturbing equilibrium,
are
to iniiai.it-
ants of
not these creatures entitled to be recjarded as accents
which have their
ofiices
to
perform in the system of
oceanic circulation, and do not they belong to
o-eography? It is immaterial how & gresit or o f J that influence may be supposed to be for, be
'='
;
we may
small,
but
it
and according
" voice
may
in the
to the
—
if
its
physical
how
small
^'"'^i'^'*'^'
to
ocean
^
it
great or
thi'msii
chance influence,
exercised at
commandment
the winds and the sea obey."
through sea It
rest assured it is not a
an influence exercised
is
design,
tli8
sea.
of
all
—by
Him whose
Thus God speaks
shells to the ocean.
therefore be supposed that the arrangements
economy of nature are such
as to require that the
§
553
^faii'ie
animals
various kinds of marine
animals, whose
secretions
are
distributed
according
calculated to alter the specific gravity of sea water, to
destroy
its
to order.
equilibrium, to beget currents in the ocean,
and to control
its
circulation, should be distributed ac-
cording to order.
Upon I'aiits
this supposition
—
the like of which nature war-
throughout her whole domain
—we
may
conceive
§
554
THE PHYSICAL GEOGRAPHY OF THE
234 cHAi'TEK
—
'-
how may
SEA.
we have been spealdng
the marine animals of which
impress other features upon the physical relations of
by
assisting also to regulate climates
and
to adjust
animals
the sea,
press'(ythei
the temperature of certain latitudes.
nrJpi^vsi"
su])pose the waters in a certain part of the torrid zone to
rionToitiie
^® ^0°>
"''^
by reason of the
^^*''
For
fresh water
instance, let us
which has been
taken from them in a state of vapour, and consequently
by reason of the propurtionate increase of waters are heavier than waters that
nut so
be
these
salts,
but
cooler,
This being the case, the tendency would be
salt.^
warm, but
for this
may
salt
and heavy water, to flow
off as
an under current towards the Polar or some other regions of lighter water. §
555
Now,
not
featurcs
sca shells
; '
and marine
upon the
;
and
as their temperature falls cm-rents,
its
and
torj)id,
its
nor give diveitsity
neither could evaporation give dynamical
force to its circulation,
impulse to
coral
and give variety to
specific gravity of its waters,
to its climates
would be no
insects could not operate ^
salt.
§ 5')(3
there
salt,
to beautify its landscape
'sl^'^'^^s
M°*^d*'f sea were
the sea were not
if
waters, ceasing to contract
its
below
39°,
and thus
would give but
its
little
would be
circulation
bosom lack animation.
its
This under current
may
be freighted with heat to
v'nder
temper some hyperborean region or to soften some extra-
freichtcd
tropical
with heat.
climatc, for „
effects of
been,
if
though quantity
we know
you its
please,
that such
.
.
marine currents.
.
At startmg,
so loaded
is .
it
among .
the
,
,
might have
with solid matter,
that,
temperature were 90°, yet, by reason of the
of
such matter held in solution,
its
specific
gravity might have been greater even than that of extratrojucal sea
water generally at »
§35.
28°.
THE SALTS OF THE Notwithstanding
this, it
may
"16.1
SEA.
be brought into contact, chapteh
by the way, with those kinds and quantities of marine that shall abstract solid matter enough to reorganisms ~ duce
than
its specific
common
gravity, and, instead of leaving
sea water at 28°,
sea water at 39° sea water,
when
it
_
make
it less
than
greater
common warm
consequently, in such a case, this
;
it
comes to the cold
would be
latitudes,
brought to the surface through the instrumentality of sh ell-fish,
and
various other tribes that dwell far
down
warm
water,
wlien it reacius colli !uti-
tudes,
biou-utro ,,y s!,t..u-
in
creatures,
though they are regarded as being so low in
the
of creation,
may
nevertheless be regarded as
much importance in the ten-estrial economy we now comprehend how they are capable of spread-
agents of for
This
Thus we perceive that these
the depths of the ocean.
scale
^—
;
ing over certain parts of the ocean those benign mantles of
warmth
less, all
wliich temper the
and modify, more or
win(.ls,
the marine climates of the earth.
The makers of
nice
astronomical
instruments,
wlien
toof their machinery they ^ ^ have put the different parts 1 I
getlier, and set °
to work, find, as in the chronometer,
it
§
558
Reautifni
and simple contnvaiice to ve-
for instance, that
it is
subject in
its
performance to man}'
siiiate
clironoine-
and imperfections
irregularities
things there tion,
among
is
to
overcome
;
that
in one
state
of
expansion, and in another state contrac-
and wheels,
cogs, springs,
diminution of
;
rate.
v^dth
an increase or
This defect the makers have sought
and, with a beautiful display of ingenuity,
they have attached to the works of the instrument a contrivance which has had the effect of correcting these irregularities,
by counteracting the tendency
strument to change
its
of the in-
performance with the changing
influences of temperature.
teis.
;
THE PHYSICAL GEOGRAPHY OF THE
236
This contrivance noraeter that
559
§
Compensrtiion.
§
perform
will
under
^.j^^g
it
may
compensation
and a
;
with certainty, and preserve
office
the vicissitudes of heat and cold to which
and regularity are maintained by a
uuiversc, ordcr
^]^g
'
A celestial
.
.
of the uni-
system of compcnsations. ^
verse.
around force
sun, flies
its
;
the planet
and held
Also in the
revolves
.
under the influence of centrifugal
ofl*
brought back to
is
in the orbit for
which
were adjusted.
its distance,
So, too, with the salts
561
of the
it
but immediately the forces of compensation begin
;
to act
machinery
body, as
*^
^
§
its
be exposed.
in the
machinery
cliro-
well regulated and properly compensated
its
all
called a
In the clock-work of the ocean and the machinery of
5G0
Analogy
is
is
SEA.
of the ocean machinery j
; >
Its
elliptical path,
its
motions, and
compensation
and the
is perfect.
shells of the sea in the
from them are derived xprinciples x
compensation the most perfect
t,f
its
mass,
its
through their agency
;
oc6iin.
tlie
undue
effects of
heat and cold, of storm and rain, in
distm-bing the equilibrium, and producing thereby currents
in the
sea,
are compensated, regulated,
and con-
trolled. §
The dews, the
562
Result
if
there were
dissolving: *=
certain
rains,
and the
rivers,
are continually
minerals of the earth, and carrying .
no com-
them
off"
This
to the sea.
is
an accumulativ^e process
pensation.
and
if it
w^ere not compensated,
become, as the Dead Sea
is,
the sea would finally
saturated with
therefore unsuitable for the habitation of
salt,
many
and
fish of
the sea. §
563
compen(sat
The sea sheUs and marine insects afford the required They are the conservators of the ocean. comveusation. "^
-^
ion
found
in
j\s
the salts
;u-e
emptied into the
sea,
these
creatures
sea shells
and the works of marine in soct*.
sccrcte
them
again, an
;
for the
"
going on
still
is
for ages
hard water" of our fountains, the
ua.
marl-banks of the valleys, the salt-beds of the Albion's chalky
monuments §
:
continually before
507
There
is
cliffs,
and the
plains,
coral islands of the sea, are
in attestation.
no proof, nor
is
there any reason fur the belief,
THE SALTS OF THE tliat
the sea
is
.
and
.
.
equal,
washing down
—
.IX.
and extraction are
reciSea grows
and
that the effect of rains
Ill
.
compensated by the processes
is
infer chapter
.
and secretion in taking
ration
Hence we
orowinor salter or fresher.
that the operations of addition procal
23.0
SE.V
rivers in c
oi
neither suiter nor
evapo-
ftesiier.
out.
If the sea derived its salts originally
the geological records of the past O ° ^
from the
rivers, §
would show that
river
568
inference.
Objection.
beds were scored out in the crust of our planet before the
'
'•'«
Darwin
sea had deposited
remains upon
any of If,
it.
theoiy,
we must
the sea
was without
its
fossi!
shells
and
we admit
therefore,
the Darwin pei'iod
when
and consecpiently without
shells
admit that there was a
also
salt,
infusorial
or animals either of the silicious or calcareous kind.
ever there were such a time,
it
were collecting and pouring
make
the brine of the ocean.
in the salts
which now
But while the
palseonto-
on one hand, afford no evidence
logical records of the earth,
any such
fresh -water period, the Mosaic account
from being negative with According ° to
it,
we
at least, as the fifth
If
must have been when the
rivers
of
tueorv
its
is
far
testimony on the other.
infer that the sea
was
salt as early.
Reductions from
day
for it
;
was on that day of
crea-
-^"saic
count
tion that the waters were
commanded
to
abundantly the moving creature that hath
bring forth It
is
iu
now teems with how abundantly the obedient waters do bring forth, and how wonderful for variety as well as multitude their progeny is. Ail who pause to look are astonished to see how the prolific ocean teems
obedience to that
organisms
;
and
command
"
life."
it is
and swarms with
that the sea
marvellous
life.
The moving
creatures in the sen
constitute in their myriads of multitudes one of the "
ders of the deep."
won-
ac
THE PHYSICAL GEOGRAPHY OF THE
240 CHAPTER
It
is
the custom of Captain Foster, of the American
IX,
-^ ^ ,.
Garrick,
ship ''
,
Captain Fosters obsevva-
who
is
one of
my
most patient of ob-
amuse himself by making o drawings o
servers,
to
abstract
log; o
'
SEA.
in hia
•/
of the curious animalculse which, with the '
microscope, he finds in the surface water alongside
tions.
though he has been following the sea never
to express his
fails
for
many
and
;
years, he
wonder and amazement
at the
immense numbers of living creatures that the microscope "Wonders j-eveals to
him
Hitherto his examinations
in sea water.
of the
related only to the surface waters, but in the log
deep."
before me he went
amazed than ever
to see
there bring forth. "
Animal-
Jan.
28th,
water,
sea
I
the depths, and he
into
1855.
how abundantly
— In
have," says he,
from the stern
examining animalculse " heretofore
pump
was
literally alive
beautiful varieties." purple, red,
There
570 as
§
571
The two
is
I
to find that the
with animated matter, embracing
Of some he
says, "
Numerous
heads,
and variegated," wonderful meaning in that word ABUNDANTLY,
stands recorded in that Book, and as
it
this
in
used surface
seven feet below the surface,
examined the water, and was surprised
§
was more
the waters even
This afternoon, after pumping for some time
water.
fluid
now
it
is
even at
day repeated by the great waters.
So t^],at
two records agree; and the evidence is clear the sea was salt when it received this command. far the
rctords 9g'*'c.
Do
they afford any testimony as to
ously
On
?
its
condition previ-
Let us examine. the third day of creation the waters were gathered
together unto
one
place,
and the dry land appeared.
Bt'fore that period, therefore, there were no rivers, and
W THE SALTS OF THE
241
SEA.
consequently no washings of brine, by mists, nor dew, nor chapter rains,
from the valleys among the This
the earth.
IX.
account which Nature has written, in her
on the mountain and in the
characters,
and
column
The
tions from
own
peculiar
and
on the rock
plain,
so,
peak
the solid parts
The
in the air,
geological evidence that
it
with perhaps the exception of a solitary mountain
and
liere
there, is conclusive
examine the
fossil
;
and when we come
remains that are buried in the
mountains and scattered over the
much
when
which now stand high
were covered by water.
was
on the geological
inscriptions
that there was a period
tell
of the earth's crust,
we have as when it covered, naturalist, when he
plains,
reason to say that the sea was salt
or nearly covered, the earth, as the
skuU or bone whitening on the wayside, has
sees a
say that
it
was once covered with
Therefore sea
and the
in the sea, as to the early condition of our planet,
indicates the same.
to
;
the account of Revelation
is
—
The water covered
hills.
was
we have " in
salt
to
flesh.
reason for the conjecture, that the
the
beoinninor," ° °
when
" the
waters
imder heaven were gathered together unto one place,"
and the dry land
we may
in the
§
572
conjecture that the se^
was
salt fi-nm
^
first
appeared.
For, go back as far as
dim records which young Nature has
the begin
left
upon the geological column of her early proand there we find the fossil shell and the remains
inscribed cesses,
of marine organisms to inform us that, tions of our
mountains were
laid
when
the founda-
with granite, and imme-
diately succeeding that remote period
when
the primary
formations were completed, the sea was, as salt
:
for, .
had
it ,
not been
salt,
it
is
whence could those
now, creep-
Reasons for thih.
.
uig things which fashioned the sea shells that cover the 16
— THE PHYSICAL GEOGRAPHY OF THE
242 CHAPTER tops
—
SEA.
or those madrepores that stiew the
of the Andes,
IX. '-
brmy
earth with sohd matter that has been secreted from deposits which
waters, or those infusorial geologist with their
astound the
magnitude and extent, or those
fossil
remains of the sea which have astonished, puzzled, and bewildered
been
salt
man
when
in
its
ages
all
;
whence, had not the sea
metes and bounds were
set,
could these
and
creatures have obtained solid matter for their edifices Effects of
.structm-es
?
IMuch of that part of the
up
in cultivation,
which
eartli's crust
nutriiie salts
on
man
stirs
has been
tion.
made
fruitful
and which yields him bread,
by these
" salts,"
which
Much
have secreted from the ocean.
shells,
of this portion of
our planet has been filtered through the sea insects
man-
all
ner of marine insects, aqueous organisms, and sea
and
;
its
and creeping things are doing now precisely what
they were set about when the dry land appeared, namely, preserving the purity of the ocean, and regulating it
As
in the due performance of its great offices.
fast as
the rains dissolve the salts of the earth, and send
down through
everlasting agents pearls, shells, corals,
and precious things
the land, by imparting
beauty and variety to
SeK-ari-
^]jj[g
justing piincipie
of nature.
sea,
new its
adaptations to
while
its
soil,
fresh
'
is
to
be found
beautiful and exquisite ^
...
systcm of Compensation, by which the operations of the -^
*'
.
most perfect 574
so,
landscapes.
this self-adiJ Ustinov o principle, r r
grand machinery of the
§
and
;
into
they are also embellishing
In every department of nature there
573
them
of the Creator elaborate
they are preserving the
§
them
the rivers to the sea, these faithful and
luiiverse
are maintained in the
order.
Whence came
the salts of the sea originally,
is
a ques-
THE SALTS OF THE
243
SEA.
tion which, perhaps, never will be settled satisfactorily to chapter
every philosophic mind
but
;
sufficient for the Chris-
it is
tian philosopher to recollect that the salts of the sea, like
waters and the granite of the
its
when reduced
substances which,
most
found, for the
mere gaseous or
Thus we say
matter of some kind or other. is
made
volatile in combination with
there
merely a
is
trace,
Now, was
tile.
the
and
of substances
oxvgen
volatile
felspar
tlien the three
Sea water
tile
is
fresh
were they made into
chaotic matter
tlie
?
find
and
them
in the
ocean, or
is
by some sub-
not material to our present purpose.
geologists suppose that in the chalk period,
when
sea,
ii
its
chambered •
1
1
shells, lived -aininK
-111 by these
the carbonaceous material required
creatm-es for their habitations
dant in
supposition re-
the ammonites, with their huge tlie
575
whether the sea was
.
i.1
§
primitive rocks, were brought together
the beginning," and became salt
.
;
and vola-
of formation, and united in combination as
sequent process,
Some
rock for the
gi-anitic
or
;
composed of oxygen and hydrogen
of the
in the process
" in
originally
But whether the constituents of sea water,
matters.
we now
granite
another, and the quartz
like the granite, also consist of gases
like those
which
brought together by some
upon
rock as they were formed of
its salts,
yet less
not gaseous or vola-
of the in
mighty power, and welded into the everlasting hills to stand
;
more or
Iron, of
g-as.
state, is
formed in one heap, the mica in a third,
sea.
the only ingredient which, in
is
uncombined and simple
its
fionotth*
that granite
generally compovsed of felspar, mica, and quartz
these three minerals are
m
are composed of
to their simple state, ai-e
to be
part,
hills,
waters than
it
must have been more abun-
now
is
;
but,
though the cou-
tlieclialk
peiiod.
THE PHYSICAL GEOGRAPHY OF THE
244'
water
CHAPTER stituents of sea
—
'-
forth,"
" its
The cuttle- feet in it
circumference,
is
twelve
shell
its
,
but then
:
the tiny nautilus, remains to
ami
with
no longer found alive in the sea
died out with the chalk period
The nauti- nion,
waters
widely different from what
It is true, the strange cuttle-fish,
§ ,j76
oorai in-
varied as to proportions,
they probably were never, at least since
commenced to bring they now are.
lus
may Lave
SEA.
us that even in
tell „
.
;
compa-
its
,
,
that Temotc period the proportion of salt in sea water
was not unsuited
to its health
have lived through
all
;
for
and the
it
coral insect
the changes that our planet has
undergone since the sea was inhabited, and they til at
its
in the
tell
us
least, as their
now
build
their
their habitations of the
same
materials, collected
records
make
waters were salt as far back, at extend, for they
same way, that they did then
edifices
and
and had the sea
;
been fresh in the interim, they too would have perished,
and their family would have become
extinct, like that of
the great ammonite, which perhaps ceased to find the climates of the sea, not the proportion of
its salts,
suited
to its well-being. §
tion of solid
Did any
577
computamat-
®
i\^Q rains, ever
ter held in
sniution as
one,
^vere orimnallv •'
who
maintains that the
washed down
into
it
salts of the sea
by the
rivers
and
''
...
take the trouble to compute the quantity
'
_
of solid matter that the sea holds in solution as salts
?
f.lltS.
Taking the average depth of the ocean at two its
average saltness at 3^ per
is salt
enough
in the sea to
cent., it
miles,
and
appears that there
cover to the thickness of one
mile an area of seven millions of square miles.
Admit a
transfer of such a quantity of matter from an average of
half a mile above to one below the sea level, and astro-
_
THE SALTS OF THE
245
SEA.
nomers will show, by calculation, that
it
would
alter the chapter
— I
length of the day.
These seven millions of cubic miles of crystal not
made
the sea any .
.
have
salt
All this solid matter has
fuller. .
increased in
;
for chemists tell us that
volume by the
therefore, started
Tins does not increase the
volume
.
been received into the interstices of sea water without swelling the mass
X.
salt
water
dissolves.
it
not
is
Here
up before us an economy of space
of
water,
is,
cal-
culated to surprise even the learned author himself of the
"Plm-ality of Worlds."
There has been another question raised which bears
upon what has ah-eady been said concerning the wliich, in the Iiave
'
•^
Condition of the Sea to
regidate
" Object ^
which, he maintains,
;"
Chapman, of
Toronto, communicated to the
on the Canadian Institute a paper ' ' intended
§
579
salts of the sea.
the 20th of January, 185.5, Professor
University College, °
the
578
sublime system of terrestrial arrangements,
been assigned to the
On
§
offices
To
evaporation."
of the Salt
Professoi
Chap^"""'^
theory on
is
" iniainly
establish
'i^e
ofthesalt-
this
nessofthe sea.
hypothesis, he shows,
by a simple but
the evaporation from
it
carefully conducted
the Salter the water, the slower
set of experiments, that ;
and that the evaporation which
takes place in twenty-four hours from water about as salt as the average
of sea water,
is
0.54
upon the wind. r
effect
with the trades very
Sand-
often,
and turn them
gular effect
and equatorial winds are common at
for westerly
;
winds.
Some hydro-
both these groups, in their winter time.
graphers have taken those westerly winds of the Society Islands to be an extension of the monsoons of the Indian
Not so they are local, and do not extend way eitlier from the Sandwich or Society Islands.
Ocean. great
:
That they are tion of sheet No.
about the former gTOup, an examina-
local 5,
a
North
Pilot Chart
Pacific, will instantly
show. §
812
It
is
a curious thing this influence of islands in the
of islands
tradc-wiud region upon the winds in the l
on
navigator
Influence Pacific
trade-
Every j
Pacific.
who has cruised in those parts of that ocean ^ "^ has often turned with wonder and delight to admire the _
winds.
gorgeous piles of cumuli, heaped up and arranged in the
most dehcate and exquisitely beautiful masses piles
found capping the
hills
among
tliat
Not only
possible for fleecy matter to assume.
it
is
are these
the islands, but they
are often seen to overhang the lowest islet of the tropics,
and even " a cloud
to stand above coral patches
by
and hidden
reefs,
day," to serve as a beacon to the lonel}'
mariner out there at
sea,
and
to
warn him
of shoals
and
dangers which no lead nor seaman's eye has ever seen or
sounded §
813
Clouds on
out.
These clouds, under favourable circumstances, gggn gathering above
low coral
tlie
island,
may
be
and performing;
theraeific, .
.
.
their office in preparing
.
it
in a very striking manner.
for vegetation
As they
and
fruitfulness
are condensed into
— THE WINDS.
34-7
showers, one fancies that they are a sponge of the most chapter
can
"
they
see, as
drop
but bountiful hand
down
would appear,
'-
their fatness," the invisible
aloft that is pressing
Maury's Sailing
out.
—
and delicately-elaborated material, and that he
exquisite
and squeezing
Directions, 7th ed.,
it
820.
p.
therefore, that these
desert countries
§
exercise a powerful influence in checking
and overcoming
No
the force of the north-east trade-winds.
There are no
It
814 exten-
fluences
check the
such extensive influences at
On
trades.
same
work checking
the south-east
the contrary, these are accelerated
south-east
for the
;
destroy the north-east trade-
forces that serve to
winds, or retard them, tend also to
draw the south-east Hence the
trade-winds on, or to accelerate them.
ability
of the south-east trade -winds to push themselves over into
the northern hemisphere.
Hence,
also,
we
infer that,
between certain
parallels of
latitude in the northern hemisphere, the sun's rays,
by
§
815
inference,
reason of the great extent of land surface, operate with
much more
intensity than they do between corresponding
parallels in
the
southern
;
and
mean summer temperature on is
higher than
south
it is
:
consequently, the
that,
shore north of the equator
a beautiful physical fact which
the winds have revealed, in corroboration of servations with the
thermometer
what ob-
had already induced
meteorologists to suspect. It appears,
from what has been the ° upon *
of the sun operating •^
which Plate
causes VIII.,
the
Now
monsoons.
arrows
it is
the rays
upon the water, ^ let
us
turn
to
The monmarked with half-bearded and half-
and examine into
soon regions are feathered
that
said,
land, not
;
and we
northern hemisphere, that
all
this
view.
perceive,
of Europe,
looking
some of
at
the
Africa,
most of Asia, and nearly the whole of North America,
§
816
cause of monsoonE.
THE PHYSICAL GEOGRAPHY OF THE
848
are to the north, or on the polar side of the north-east
c:iAPTER
—
SEA.
trade-wind zone
'-
whei'eas but a small part of Australia,
;
of South America, and
less
of South Africa,
less
still
are situated on the polar side of the zone of south-east
In other words, there are on the polar
trade-winds.
side of the south-east trade-winds
Australia,
in
summer enough
upon which
no
gi^eat plains,
except the
the rays of the sun, in
of the other hemisphere, can play with
force
to rarefy the air sufficiently to materially interrupt
these winds in their course.
But, besides the vast area
of such plains in the northern hemisphere, on the polar side of its trade-wind belt, the heat of
to
draw
these trade-winds back, there are
districts in the exti-a-tropical
summer heat
the
which
it
be not sufficient to
turn the north-east trade-winds back, and
their force, and,
may
numerous other
regions of our liemisphere,
of which, though
soon of them, yet
is sufficient^
make a mon-
be sufficient to weaken them in
by retarding them,
di'aw the south-east
trade-winds over into the northern hemisphere. §
817
Remarks on interferenceof land.
Now, as this interference from the land takes place infer, without appealing summer ouly, we miffht i t o ^
^j-^g
-^
'
'
of these trade-^vind ^ctual observatiou, that the position ^
zones
is
variable
;
that
that the equatorial edge of the
is,
south-east trade- wind zone
is
farther to the north in our
summer, when the north-east trades are most it is
§
818
in
to
in winter,
We
have
when they
uow wcak, now
goucs, a forcc
trade-wind
^vould causc thcsc zoncs
'
work upon
here, th.en, at
Fnrceat work on
feeble,
than
are strongest.
which, of course, strong, o' '
'
to
these trade- wind
vibrate
up and down the
Eou es.
ocean,
and within certain
of the year.
limits,
according to the season
These limits are given on Plate VIII. 1
§810.
2
§815.
for
— o^Q
THE WINDS.
chapter Durinospring ° the latter season these zones ^ ^ and autumn, XIV. , our in ana declination, northern extreme reach their .
spring their utmost limits toward the south.
Changing of
the
Monsoons.
—
Lieutenant Jansen, in
phenomenon
describes this "
We
§
819
work, thus
his appendix to the Dutch edition of this
J^^"^^^^°^,
'"^ °^
:
have seen^ that the calms which precede the sea-
breeze generally continue longer, and
with an upward motion of the air
;
that,
accompanied
are
on the contrary,
those which precede the land-breeze are, in the Java Sea,
generally of shorter dui'ation, accompanied
atmosphere; and that there
also
is
by a heavy
an evident difference
between the conversion of the land-breeze into the breeze
and
sea-
of the latter into the former.
Even as the calms vary, so there appears to be a § 820 marked difference between the changing of the monsoons ^~^^ As sea. in the spring and in the autumn in the Java Sea. "
soon as the sun has crossed the equator, and
its
vertical
rays begin to play more and more perpendicularly upon the northern hemisphere, the inland plains of Asia, North
and of North America, are so heated, as to give monsoons in the China Sea, in the North Indian Ocean, in the North Atlantic, and upon the west coast of Central America then the north-west mon-
Africa,
birth to the south-west
:
soon disappears from the East Indian Archipelago, and gives place to the south-east trade-wind, which east
monsoon
;
is
just as the north-west wind,
during the southern summer,
is
known
as the
which prevails
called the west
monsoon. 821
This is the only monsoon which is found in the , •! n 1 i.1 southern hemisphere, while in the northern hemisphere the
Monsoons
north-east trade-wind blows in the China Sea and in the
spheres.
"
.
•
1
'
1
§ 262.
•
1
§
in differ-
—
—
THE PHYSICAL GEOGRAPHY OF THE
850 CHAPTER Indian
Ocean
in the East Indian Archipelaf]jo tlie west
;
XIV.
_
monsoon
SEA.
prevails
and
;
when we find
here,
blows as the east monsoon,
the south-east trade
mon-
the south-west
soon in the adjacent seas of the northern hemisphere.
summer
Generally the westerly monsoons blow during the
months of the hemisphere wherein they are found. §
"
822
Winds de-
As
the land-breeze
"
stroy each
monsoon
otiier.
daily destroys in miniature the
regular flow of the trade-wind, so does the latter the west in larger
measure and observations will be able to ;
decide whether monthly disturbances do not also take place. §
823
"
Monsoons in Java
-^^est
Sea
it
dming
In the Java Sea,
monsooH blows
month
the
of February, the
almost contirmally
strong; °
"^
March
in
;
blows intermlttiugly, and with hard squalls
;
but in
April the squalls become less frequent and less severe.
Now
the chanoinoj commences.
spring up from ^
calms. clear
the east
All at once o-usts beo^in to
they are often followed by
:
The clouds which crowd themselves upon the
sky give warning of the combat in the upper
which the currents there are about to wage with each §
824
Electricity
"
The
driven
electricity,
thereby out of
channels, in which, unobserved, silently,
but with the
full
;
its
it,
now
sheen and
its
its
power, the
displays itself with
voice
with as-
fill
tonishment and deep reverence the mind of the so susceptible, in the presence of storm
impressions
that
inspire
feelings
sailor
and darkness,
both
of
by pretended occupations he
anxiety, which
natural
has been performing
consciousness of
mysterious task appointed to dazzling majesty
it
its
air
other.
dread
to
and
strives
in
vain to conceal* *
No phenomenon
dark tliuuder-storui
in nature in
makes a deeper impression upon the
a calm at sea.
Jansen.
sailor
than a
—
THE WINDS. "
Day aud
351
we now have
night
The
thunder-storms.
clouds are in continual
movement, and the darkened
laden with vapour,
in all directions througli the skies.
flies
The combat which the clouds seem to court and appears to
make them more
tunnel form,
them
tliirsty
to
when time and
quench their
thirst
dread
themselves
op[)ortunity
fail
to
—
'-
They
than ever.
extraordinary means to refresh
sort to
to
cuaptek
air,
:
|hu^f,(.,.
^^°™^
re-
in
allow
from the surrounding atmos-
phere in the usual manner, they descend near the surface of the sea,
and appear
their black mouths.
to lap the
water directly up with
Water-spouts, thus created, are often
""'atersiiouts.
changing
the
seen in
especially
season,
among
small
groups of islands, which appear to give rise to them.*
The water-spouts are not always accompanied by strong winds
;
frequently more than one
is
seen at a time, where-
upon the clouds whence they proceed disperse directions,
and the ends
finally causes
water which
them is
"
of the Avater-spouts bending over
to break in the middle, although the
now
suffered little or
in various
seen foaming around their bases has
no movement
laterally.
Yet often the wind prevents the formation of waterIn their stead the wind-spout shoots up like an
spouts.
§
82G
^^'""i-
spouts,
arrow, and the sea seems to try in vain to keep
The
sea,
lashed
into
fury,
it
back.
marks with foam the path
along which the conflict rages, and roars with the noise of
its
water-spouts
;
and woe
to the rash mariner
who
ventures therein If * I never saw more water-spouts than in the Archipelago of Bioun Singen, during the changing. Almost daily we saw one or more. Jansen. t The air-spouts near the equator always appear to me to be more dangerous
than the water-spouts. I have once had one of the latter to pass a ship's length ahead of me, but I perceived little else than a water-fall in which I thought to ojme, yet uo wind. Yet the water-spouts there also are not to be trusted. I
—
THE PHYSICAL GEOGRAPHY OF THE
352 CHAPTER
"
The height of the spouts
usually
is
SEA.
somewhat
le.su
than 200 yards, and their diameter not more than 20 ''
Height of spouts.
feet,
yet they are often taller and thicker
when
;
tlie
opportunity of correctly measuring them has been favourable,
however, as
tween the
it
generally
be accurately determined, higher than 700 ber, in the Duration
-^vest
ells,
have
I
never
nor thicker than 50
found them In Octo-
ells.
Archipelago of Bioun, they travel from south-
to north-cast.
minutes
was when they passed be-
islands, so that the distance of their bases could
They seldom
last longer
than
generally they are dissipated in less time.
;
they are going away, the bulbous tube, which
is
five
As
as pal-
pable as that of a thermometer, becomes broader at the base,
and
little clouds, like
steam from the pipe of a loco-
motive, are continually thro\vn off from the circumference of the spout,
and gradually the water
is
released,
cloud whence the spout came again closes
its
and the
mouth.*
have seen such spouts go up out of the water upon the shore, where they overthrew strong isolated frame-houses. I have, however, never been in a situation to observe in what direction they revolved. Jansen. * Miniature water-spouts may be produced artificially by means of electricity, and those in nature are supposed to be caused by the display of electrical phenomena. "From the conductor of an electrical machine," says Dr. Bonzano of New Orleans, " suspend by a wire or chain a small metallic ball (one of wood covered with tinfoil), and under the ball place a rather wide metallic basin containing some oil of turpentine, at the distance of about three quarters of an inch. If the handle of the machine be now turned slowly, the liquid in the basin will begin to move in different directions, and form whirlpools. As the electricity on the conductor accumulates, the troubled liquid will elevate itself in the centre,
become attached to the ball. Draw off the electricity from the conresume its position a portion of the turpentine remains Turn the handle again very slowly, ami observe now the attached to the ball. few drops adhering to the ball assume a conical shape, with the apex downward, while the liquid under it assumes also a conical shape, the apex upward, until both meet. As the liquid does not accumulate on the ball, there must necessarily be as great a current downward as upward, giving the column of liquid a rapid circular motion, which continues until the electricity from the conductor
and
at last
ductor to
13
nearly
let tlie liquid
all
discharged silently, or until
:
it is
discharged by a spark descending
—
—
;
THE WINDS. " Durin2f the
353
...
of the monsoons,
cliano-insr
.
cahn or
and
with
cool,
light gales
e-entle breezes,
from
all
Avitli
xi\'-
They
the chano-ini:^ o o
sails to
i.
However, the atmosphere generally becomes
winds.
and, contrary to expectation, the north-west
from a clear sky
Now
northerly.
wind
827
tiic
tea-
||,'g'^t|Je''
changes
m
monsooni
clear,
wind comes
about the coming of the monsoon
:
§
are
burning faces under the
clouded skies,* impatiently J trim the
the
mostly cnAPTER
varied with rain-storms
points of the compass.
harassing to the crew, who, >
it is
it is
the clouds are again packed together
but
dies away,
will soon be
it
come again from another
point.
waked
Finally,
up, to
the regular
land and sea breezes gradually replace rain and tempests,
The
calms and gentle gales. day, is
and in the Java Sea we have the
the east
up during the
east monsoon.
It
Farther to the south than the Java Sea
then May.
"
rain holds
monsoon commences
in April.
7
This monsoon prevails in September and October,
when
it
turns to
become the west monsoon.
It has
§
828
East monsoon.
seemed to
me
that the east
same in every month f that
into the liquid.
Tiie
latter liquid, the ball
If,
in this experiment,
will travel over its
its
direction becomes
more
same phenomena take place with oil or water. Using the must be brought much nearer, or a much greater quantity
of electricity is necessary to raise
"
monsoon does not blow the
we
miniature
let
sea,
it.
the ball swing to and fro, the
carrying
its wliirl[iools
little
water-spout
along with
it.
When
breaks up, a portion of the liquid, and with it anything it may contain, remains attached to the baU. The fish, seeds, leaves, &c., that have fallen to the earth in rain-squalls, may have owed their elevation to the clouds to the
it
same cause that attaches a few ties, to
di-ops of the liquid,
with
its particles
of impuri-
the ball."
* At sea the face and hands burn (change the skin) clouded than under a clear sky. Jansen.
much
quicker under a
•f- In the north-east part of the Archipelago the east monsoon is the rainy m^mEoon. The phenomena in the north-east part are thus wholly different from those in the Java Sea. Jaksen.
>
§851.
23
—
—
THE PHYSICAL GEOGRAPHY OF THE
So-t CHAPTER southerly,
and
its
power
SEA.
greater, after it has prevailed for
XIV.
some §
829
Effects of
time.''
" It is sufficiently
important to
fix
the attention, seeing
these circumstances have ° CTeat influence upon the winds iu the many straits of the Ai-chipelago, in which
tiiat
monsoon in straits of
*'
the Archi-
Especially in the
very strong.
straits to the east of Java, these cm'rents are I
have been unable to stem the current with eight-mile
However, they do not always flow equally
speed.
They
nor always in the same direction. strongest
when
straits durino; the east
north,
'
iQn.
and
east monsoon,
Chanseof monsoons on Java
"
As
said that the cm-rents in the
monsoon run eighteen hours
and
the sea
It is
and the reverse during of the meridian
by
the
is
probable that the heated water
discharged to the north during the
to the south during the
makes the coming
j^^Q^yn to the inhabitants of the
of the east
to the
to be the fixed point of time for the turn-
of the Archipelago
830
is
The passing
ing of the currents.
§
It
six hours to the south,
the wcst mousooiL
moon appears
strong,
are probably the
the tidal current and the equatorial cur-
rent meet together.
Mnnnpass-
.
.
_
strong currents inin most of the time.
peiago.
monsoon
west monsoon.
of the southern
summer
Java coast.i the turning o '
into the west
'
monsoon commences.
coast.
After the sun has finished hemisphere, and brings •
As
is
its
its
yearly task in the northern
powerful influence to operate
well known, the Strait of Soerabaya forms an elbow whose easterly
outlet opens to the east, while beginnin;;; of the east
tlie
westerly outlet opens to the north.
monsoon the sea-winJ
(east
westerly entrance as far as Grissee (in the elbow)
;
In the
monsoon) blows through the in the latter part of this
mon-
soon, the sea-wind blows, on the contrary, through the easterly entrance as far
as Sambilangan (the narrow passiige where the westerly outlet opens into the sea). •j-
tlie
Janskn.
In the Archipelago we have generally high water but once a day, and. with equinoxes, the tides also turn. The places which have hi^h water by day in
one monsoon get
it
at night in the other.
Jaksen.
THE WINDS.
8.55
a chanci;e in the southern hemisiihere, ^ '
is
chaptkb at once ])erceived ^ XIV.
in the constant fine weather of the east
Java
As soon
Sea.
Sea
and
in the upper
to resist the
north-west
Upon and
less
seem to have
make
and west,
over from
definitely if
known.
superioiity
their
in the neighbourhood of
The atmosphere, alternately
appears as
sufficient strength
aggressors, who, with wild storms from the
storms occur, but at sea they are
more
so continuous.
atmosphere appears to be
the south-east trade, which has blown as the
;
east monsoon, does not
"
height upon the Java
The calms then are not
spring tm-ning.
violent
its
accomplished much more rapidly than the
is
The combat
at
is
it
tlie
then the true tui-ning of the monsoon
(6° south),
begins,
as
monsoon of
the land, thunder-
less frequent.
clear
the
and cloudy, moves
north-west,
§
831
it *f"^e'"eiit
that
so
no combat were there waged, and the south-
spue-.e.
east gives place without a contest. " The land-breezes become less frequent, and the pheniolit become, in a certain sense, nomena by J and by J o J day Storms of wind and more accordant with each other. '
^
§
832
^'^'^''^-
breezes
^
'ess fre-
quent.
rain beneath a clouded sky alternate with severe gales
and steady winds.
monsoon "
is
In the
last of
November
the
west
permanent.
Such are the
shiftings.
But what have they
to
do
with the general system of the circulation of the atmos-
§
833
wimtthe '•shift-
pliere .
Wlienever we
?
read
attentively
the
beautiful
meditations of the founder of the Meteorology of the c
the month, and from the course upon which he to
make an
scores,
will
thus
make
entry, he has (||||).
the
fifth
;
is
about
akeady made fom' marks
or
The one that he has now to enter and he " scores and tallies," and so
on, until all the abstracts relating to that part of the
ocean upon which he
is
at
his materials exhausted.
work have been gone These "
fives
and
over,
and
tallies" are
exhibited on Plate V. §
932
neference to Plate V.
Now, with tliis explanation, marked A (Plate V.), ^ ''
district
it
will be seen that in the
there have been examined
the logs of vessels that, giving the direction of the wind for every eight hours,
to enable
me
have altogether spent days enough
to record the calms
and the prevailing
tion of the winds for eight hours, 214-i times
285 were
for the
month
of September;
observations for September the wind
is
:
direc-
of these,
and of these 285 reported as
pi-e-
407
STORMS. vailing for as
8 times
as eight hours at a time
from N.N.E.,
;
];
E.S.E.,
much
S.W, 93
;
N.N.W.,
1
S.E.,
4;
Calms, 5
;
;
2
N.E.,
;
;
E.N.E.,
1
chapter
E,
;
25; S.S.AV., 45 W., 47 W.N.W., 1 7 N.W, 15 total, 285 for tins month in tliis 2;
S.S.E,
W.S.W., 24. ;
1
from N.,
:
S.,
;
;
—
district.
The number expressed
number
of observations of calms and winds together that
month and
are recorded for each
In
C, the
west.
But
wind in A,
May
in
which
district.
one-third of the time from
sets
between the same
is
the favoui'ite quarter for the same to south-west, the
wind
;
or,
month
is
parallels,
from
§
934
'^^'"'J'n
soutli
setting one-third of the time for
that quarter, and only 10
west
whole
in figures denotes the
on the average,
out of 221 times from the it
blows from the west only
I3 day during the montli of May.
In B, notice the great
"
Sun Swing"
of the winds in
September, indicatino; that the chano-e from winter, in that region, ° to summer, gentle
In some
is
sudden and violent
;
'
summer
to
from winter
§
935
"^"" "''"'i» '"
September
and gradual.
districts
of the ocean,
more than a thousand
Number
of
otiserva-
observations have been discussed for a single
month
whereas, with regard to others, not a single record
be found
in
is
;
tions
made
to
any of the numerous log-books at the National
Observatory.
Typhoons.
—The China Seas
furious ° (jales of wind,
'
and white
squalls.
are celebrated for their
known among » seamen
as typhoons ''
J-
These seas are included on the plate
(VIII.) as within the region of the
Ocean.
monsoons of the Indian But the monsoons of the China Sea are not five-
month monsoons;^ they do not
prevail from
south for more than two or three montlis, '
§ 788.
tlie
west of
§
936
Typhcnna in Chins ^''^
408
THE PHYSICAL GEOGRAPHY OF THE
SEA.
Plate V. exhibits the monsoons very clearly in a part
CHAPTKR XVII
In the square between 15° and 20° north,
of this sea.
§937 110° and 115° ilonsoona as exhiliitert
on
Plate V.
monsoons ber,
;
east, there
that
is,
appears to be a system of three
one from north-east in October, Novem-
December, and January
April, changing in
in June, July,
;
one from east in March and
May and
another from the southward
;
and August, changing
in September.
The
great disturber of the atmospheric equilibrium appears to Arid plains
bc situatcd
01 Asia.
among the °
arid plains of Asia '
their influence
;
^
extends to the China Seas, and about the changes of the
monsoons these awful
gales, called
typhoons and white
squalls, are experienced. §
Time
In
938 of
like
manner,
Mauritius
the
hurricanes,
or
the
Mauritius hurricanes
cyclones of the Indian Ocean, occur duiina: O the unsettled state of the atmosphcric equilibrium which takes place at
cyclones of Indian
that debatable
Ocean.
tradc-wiud
'
•'
period during the contest between the
,
and the monsoon
force
force,'
and which
debatable period occurs at the changing of the monsoon,
and before ascendency.
either force has completely gained or lost the
At
this period of the year, the winds, break-
ing loose from their controlling forces, seem to rage with
a fury that would break up the very fountains of the deep. §
939
West and Last India hurricanes
So, too, with the TlicsB
West India hmricanes
of the Atlantic.
wiuds are most apt to occur duriufj the months of ^ =>
August and September.
There
is,
therefore, this
remark-
able difference between these gales and those of the East
Indies
:
the latter occur about the changino- of the
soons, the former during their height.
mon-
In August and
September, the south-west monsoons of Africa" and the south-east monsoons of
1
§ 796.
the
»
West
§ 810.
Indies'* are
«
§ 737.
at
their
409
STORMS. heiojlit
tlie
;
aoent of one drawinnj the noiih-east trade-
winds from the Atlantic into the interior of
New
ohapteii XVII
Mexico
'
and Texas, the agent of the other drawing them into the interior of Africa. directions, assist
two
Its
forces,
now and then
pulling in opposite
to disturb the atmospheric
equilibrium to such an extent that the most powerful revulsions in the air are required to restore
The hurricane season
"
says Jansen, " occurs
monsoons
and
;
in the
it.
North Atlantic Ocean,"
simultaneously with
in the
the African
same season of the year
which
in
§
940
Jansen's
remarks on imnicaiies
the monsoons prevail in the North Indian Ocean, in the
China Sea, and upon the western coast of Central America, the seas of the northern hemisphere have the hurri-
all
On
cane season. has
its
the contrar}^, the South Indian Ocean
hurricane season in the opposite season of the
and when the north-west monsoon prevails
year,
in
the
East Indian Archipelago. "
In the South Pacific and in the South Atlantic, so
far as I
know,
i-otatory
storms are never known, and these
§
941
^°"!'^ i iiCltlC
seas
have no monsoons.
Such a coincidence of
liurricanes
''"''
so""*
.\tlantic
with monsoons, and of the hurricane- season with the monsoon-season,
is
not without signification.
It ever gives
rise to
the thought that the one disturbance causes the
other
and however
;
terrible the hurricanes
may
be to
us,
however disastrous they may appear, yet we are compelled to
acknowledge therein the healthful workinf; of Nature,
wliich
compensating over
is
all
and in
all.
We
need
doubt that these revolving: o storms have a determinate task to perform in the economy of nature n(^t,'
-
—a
then, '
task which they cannot otherwise
rotations
;
and certainly
it is
fulfil
save
by
good that they restore iu
^^^o'^"*? storms.
THE PHYSICAL GEOGRAPHY OF THE
410
CHAPTER proportion to
—
the
power
terrible
SEA.
wlierewitli
they are
XVII.
§
"
942
ofiiRhtiiiiiff
intrusted.
We
know
do not
all
tlie
which are
disturbances
caused by the land in the condition of the atmosphere.
and
thunder.
'
Ths way
of the lightning of the thunder'
The
unknown.
is
to us all
circulating channels of electricity are as
yet hidden in a deep night. §
943
Remarks on tlie nsesof
"
know what
Neither do Ave
influence the land
^varm currcuts in the sea have thereon,
know
—even
less
and the than we
wluit Operations are appointed for the hurricanes in
liunicanes
the
economy of nature
;
but that they, in their way, have
The
important services to perform, cannot be doubted.
almighty and merciful Wisdom,
whom we
find universally
—
in all the operations of nature, assures us thereof
us a pledge.
The
their feet in
warm
prevail to arise
warm
water, and that in
water currents
work
where they
which appear
solid crust of the
of the waters of the
reiri^lar flowincj
us to suspect that there
between the hurricanes and the warm
seas
all
settled currents are also found,
earth causes in the
jrnnicanes and
to
fact that the hurricanes prefer to place
from the disturbance which the
sea, causes
is
is
a certain relation
warm
currents
;
and,
economy of nature the hunicanes in the atmosplicrc and the warm 'rivers in the sea' work finally,
that in the
•'
together to restore the disturbed equilibrium in nature,
together.
m
which can be done
no other
the wa}^ which they, as
Thus we
together.
follow surface,
side
the
most
it
way than
this,
and along
were, mutually agree to follow
see the hurricanes
prevailing
beyond the
current of
air
tropics
along
the
on one side from the south-west, on the other
from the north-west
to the north
and
east,
;
just as the Gulf Stream flowf^
and the warm currents of the South
411
STORMS.
Indian Ocean to the south and current to the north and east.
by which
universal laws
touching "
is
their
1
latitude
we
In this matter
all
is
the China chapter XVII.'
the
see, again,
governed
:
very-
the simplicity of the divine plan.
When
upon
east, and, again,
the
way ./
hurricanes and the to the poles, i
'
which the upon *
'
rivers
in
have reached the
effort of the
the
sea,' §
parallel of i
diurnal revolution
of the earth upon her axis causes air and water to
be
944
^*'"'^'^'
"^
diuinal resolution of the earth
"P"" "« axis.
forced in a north-easterly or south-easterly direction, then
bow
they
themselves submissively to the law, and go
together, often tasks.
hand
And now,
in hand, to accomplish their appointed if
we suppose
revolution everything which this parallel east,
then
of
it is
latitude
is
that by the diui-nal moves from the equator to bent more gradually to the
remarkable that the
first
part of the course
of circulating storms often stands perpendicular to these
supposed movements of the
air,
Ocean runs nearly W.N.W.
;
and
in the
in the
North Atlantic
South Indian Ocean,
W.S.W. " Hui'ricanes
are sometimes observed upon the limits
and upon the
of the African monsoon,
soon of the
East Indian
limits of the
Ai-chipelao^o. i o
mon-
In this Archi-
pelago huiTicanes or right heavy spouts are seldom seen,
However, hurricanes have been observed in the southern hemisphere, between 88° and 90" east longitude. They are also found in September in 13° north latitude
and
29° west longitude, and in 16° 83' north latitude and 24;° 20' west longitude the latter also in 18° north latitude and 25° west longitude, and in 16° 30' north latitude and 26° 40' west longitude;* yet not the mon;
m
*
KetHleW.
§
945
,^i)^e^.ehu'^
P'^''"f have been o^^ei-ved.
412
THE PHYSICAL GEOGRAPHY OF THE
—
CHAPTER soon xvir.
.
SO
much
.
is
known
limits
;
to
me
—but
.
,
SEA.
ricrlit
upon
its
.
in the equatorial belt which wavers about
also
the monsoon, and which becomes narrower and narrower as §
"
946
Combats in the air conse-
recedes from the equator.
it
Now, when we remember what
is said' '
^
tlie
of the spring
with southern hemisphere, which agrees 1 o » autumnal changino; in the northern hemisphere, and
chanffincf o in the
^
quent on the changing
think of the combat which
of spring
between the various currents of
and autumn,
spouts whicli arise in the East Indian Archipelago
,
.
.
.
is
then so manifestly waged air
and the numerous
we
aid of small groups of islands, then
prised to find a similar effect produced
when
the African monsoon, especially torial belt of
Yerd
When we
tlie
;
limit of
pushes the equa-
take into account that this belt
becomes narrower and narrower as
draw
shall be less sur-
upon the
calms quite over to a portion of the Cape
Islands.
the equator
it
by the
it
is
removed from
that also the different currents of
air,
in opposite directions, lie closer to each other
which that
;
south-west and north-west winds approach very near
to each other,
and that the
in
latter,
August and Sep-
tember, are deflected out of their course by the heights Cause of
^f
^^j^g
Cape Verd Islands
;
—then
not
much more
why
sary to enable one to comprehend
is
neces-
a wind whicli,
coming from the north-east, and veering by the around to the north-west, should, as
it
nortli
meets the south-
west winds, make a complete revolution, and in so doing
form a whirlwind, which would go travelling through the north-east and south-east trade-winds, especially
when
the moistui'e and electricity of these air-currents are ferent,
as
is
generally the case.
the north-east trade-wind, as *
it
§820,
And
dif-
seeing also that
draws more and more
413
STORMS.
toward
north,
tlie
monsoon,
it
may
lies
south-west chapter
tlie
why
be readily conceived
the motion
'
be from the right hand to the
of this whirl should left,
the left of
to
movements of the hands
or contrary to the
of a
watch. "
Thus,
circular
when upon
the limit of the African monsoon a
motion in the
situation of the currents of other, that the
the
left.
we may
air arises,
movement
air, .,,
and
their relation to each
from the right side to
will be
hand
For the same reason, the motion to the right.
way
;
south-west turned back south-east,
north-west monsoon.
Therefore,
is
left
hand
motions of the winds circum-
from the find the
the south-east, or the to the left of the
is
when
a circular motion
there takes place upon the limit of the monsoon,
go from the
947
circular
in the soutli-
Near the north pole we
cui'rents of air just the other
§
in various
„
,
ern hemisphere, in the South Indian Ocean, left
from the
infer,
it
must
to the right, or with the hands of
a watch, "
The want of knowledge prevents me from venturing
to penetrate into the
'
hidden chambers out of which the
§
948
^mpossibillty of
^
whirlwind comes,' for the circulation of the atmosphere
anivingat definite
must, like the revolutions of
human
society, bring all tlie
conclusions.
natural forces
into commotion,
and
they,
in
the strife
which they wage, become renewed and strengthened to perform their appointed work for the universal welfare,
and pass away accomplished indeed, I
—
is
its
may
violent,
like the all-destroying meteor, after
terror-awaking mission.
call
The
having
strife
—
if,
the opposite workings in nature strife
terrible.
The monsoon has attained
greatest strength, the disturbance
the atmosphere has reached
its
its
in the circulation of
utmost
limits,
the vapour
— THE PHYSICAL GEOGEAPHY OF THE
414 CHAPTER
and the heavy clouds act
in
harmony no
SE.\.
longer,
and with
XVII, '
wild violence the uproar, nursed in
way
'The
silence,
breaks
forth.
for the lightning of the thunder' appears to he
broken up.
§949 Humsoutii
Indian Ocean.
In the South Indian Ocean (25° south
"
latitude), a
was observed,* by which several of the crew were made blind, others had their faccs cut opcu, and those who were in the rigging had The master of the ship their clothes torn off from them.
hurricane, accompanied
compares the sea with snow.'
by
hail,
to a hilly landscape in winter, covered
'
Does
not appear as
it
the
if
treasures of
'
the hail' were opened, Avhich were 'reserved against the
§
950
Furious
time of trouble, against the day of battle and war?' "f In the extra-tropical regions ExTPvA-TEOPlCAL Gales.
—
of
each
hemisphere furious gales of wind also occur.
gales in
the extra-
Quc
.
of thcsc, remarkable for
its
violent effects,
was en-
tvopical
regions,
Wreck,
countered on the 24th of December 1853, about three
hundred miles from Sandy Hook, latitude
39° north,
longitude 70° west,
steam-ship.^
by the San Francisco
That ship was made a complete wi-eck
and she was abandoned by the
by the
nell),
§
951
F.xtract
"
flie
"Eagle
Wing
from Boston to San Francisco.
tudc 62° 32' west.
after
(Ebenezer H. Lin-
She encountered the
and thus describes
Decemher 24, 1853.
from log of
Some months
California mail the abstract
log of the fine clipper-ship Eagle
ill-fated steamer's gale,
few moments,
survivors, after incredible
hardships, exertions, and sufferings. this disaster, I received
in a
— Latitude 39°
it
:
15' north, longi-
First part threatening weather
^
I
:
short-
\
, ^j
mn]m, Captain Brandlijrt. + Natuurkiimlige Bescliryving der
Zeeen, donr M. F. Maury, LL.D., Luitenant der Nord Amerikaansche Marine, vertaald door M. H. Jansen, Luitenaut ter Zee.
Dordreciit, P.
K. Braat, 1855.
>
ssa.
—
— STORMS.
ened
sail.
the courses.
At 4 At
p.ji.
415
close-reefed the top-sails
and furled
chapter
8 p.m. took in fore and mizzen top-sails;
'
hove to under close-reefed main top-sail and spencer, the lying with her lee rail under water, nearly on her
sliip
At
beam-ends.
30
1
masts went over the
At
bowsprit-cap. I
my
In
mam
a sea took away jib-boom and
;
thirty-one years' experience at sea,
have never seen a typhoon or hurricane so
two men overboard
my
;
top-gallant-
blowing a perfect hurricane.
side, it
8 A.M. moderated
and
A.M. the fore
saved one.
Lost
severe.
Stove sky-light, broke
barometer, &c., &c."
Severe gales in this part of the Atlantic polar side of the calm belt of Cancer '
the months of June,
Jid}^,
—
i. e.,
on the
occur duringo August, and September. This rai-ely ./
appears to be the time wlien the fiends of the storm are
952
§
"^''^ewiien
severe sales sel-
dom
occur
in particular part of
most busily at work in the West
Indies.
During the
remainder of the year, these extra-tropical
gales, for the
most
part,
come from the noi'th-west
the most famous season for these
time
when
;
but the winter is
is
tlie
the Gulf Stream has brought the heat of sum-
mer, and placed
it*
cold of the north
;
in closest proximity to the extremest
and there would,
therefore, it
seem, be a conflict between these extremes great disturbances in the cold to the
That
gales.
Atlantic.
air,
;
would
consequentl}',
and a violent rush from the
warm.
In like manner, the gales that most prevail in
953
tlie §
extra -tropics of the southern hemisphere come from the pole
and the
west,
i.
e.,
south-west.
Storm and Rain Charts ah-eady been published for the
for the Atlantic
Ocean have
by the Observatory, and
whole seas are in process of construction.
§
954 ^"'^
others
The __^____.
KaT SeTtilntic.
4
THE PHYSICAL GEOGRAPHY OF THE
6
1
show the
CHAPTER object of such charts is to
frequency of gales in
frequency of calms, What
^]^rj^ i^r^lf
charts
covers the northern hemisphere ^
Bhow.
;
and
rela-tive
the relative
thunder, and lightning.
fogs, rain,
They show that
These charts are very instructive.
955
§
directiotis
parts of the sea
all
SEA.
Qf Q^Q atmospherical coating of the earth
—
we may
if
-^
which
take as a
type of the whole what occurs on either side of the equator in the Atlantic dition than that §
There
956
Rain storiBsand
Mims
in
North and South Atlantic.
morc
are, as
calms, '
Ocean
—
in a
is
which covers the a
more
more
rule, fosfs,'
o
much
rains,
more gales
and more thunder and
North than in the South Atlantic.
in the
con-
less stable
soutliern.
of wind, lifchtnino-, o o'
These pheno'
mena, at equal distances from the equator north and ^ ^ _
south,
—
and
that
for all
is,
every 5° of latitude, have been compared
the storms, calms, rains, &c., between the
parallels of 25° and 30° north,
for instance,
compared with the same between the 80° south
;
;'
have been
parallels of 25°
and
those for January north being compared with
those for January south, and so on for each month, be-
tween
all
the five degree
(5°,
10°, 15°, &c.) parallels
from
the equator to 60°, north and south. §
957
t^onT eases.
In some places here and there, and in some months
^^^ ^^^
then, there
may
be more
gales, as in the neigh-
bourhood of Cape Horn, in the South than in the North Atlantic
;
but such cases constitute the exceptions, they
by no means the rule. Cape Horn in the South Atlantic, and the Gulf Stream in the North, furnish seats are
for agents whicli are very
marked
in their workings.
This
Plate brings out the fact that, as a rule, rains and calms go
together in the tropics; but beyond, rains and gales are
more apt
to occur at the
same time, or 1
Plate XIII.
to follow each other.
— 417
STORMS.
With regard to the disturbing agents which are let loose from Cape Horn and the Gulf Stream upon the atmosphere, I
beg leave to quote a remark of Janseu's
"In contemplating Nature in her universal which
all
is
aspect, in
with
"•
mutual kindness suppoi't each other by the complaisant interposition of air
—
XVII.
:
ordered that all the parts so perfectly " '^
chapteb
and water, we cannot possibly
reject
§
958
Jansen-s
remarks "nfiis-
agents loose
the idea of unanimity of action
;
that when, impeded or prevented
bond of union
their
is
shown
so
little,
by external
local causes,
broken, then are observed the
ten-ible efforts of Nature, is
and we may conjecture
by which
its
almighty power
which we know
in combating that disturbance of
and in renewing and perfecting those broken
bonds.
Forces which are otherwise working beyond the
reach of
human
vision then
come
the earth to tremble to her centre, and
anxious and dismayed.
is
for
They cause
man
to stand
Yet Omniscience watches, a Pro-
vidence cares, and the Almighty
land that
combat
forth in the
the restoration of the disturbed equilibrium.
The
is love.
given us as a dwelHng-place
is,
delightful
at the
time, the cause of all the disturbances in the air
same
and in
the ocean, whence the hurricanes and the 'rivers in the sea'
arise,
which in tm-n are
for
the
universal good
;
where they are not found, we may be certain that the cuiTents of the air and of the water
harmoniously together.
And
is
work undisturbed,
not this th^ case in the
south-east trade-wind of the South Atlantic Ocean ?"
27
let
upon
tiieatmo-
4
J
THE PHYSICAL GEOGRAPHY OF THE
8
CHAPTER
SEA.
XVIII.
ROUTES.
—
How closely Vessels follow each Passages have been Shortened, § 959. Track, 961.— The Archer and the Flying Cloud, 962. The great
How
otlier's
Race-course upon the Ocean, 964.
— Description of a
Knowledge of the Winds enables the Navigator
CHAPTER
The
to
Ship-race, 966.
compute
— Present
his Detour, 991.
principal routes across the ocean are exhibited on
XVIII.
Plate VIII. §
959
the oreai end and aim of
;
.
.
aU
this labour
and n
•
,
.
The great
^search are in these, and consist in the shortening of
eli'rtonhe
P^^sages
authov-3
hibouiS
and
'*"'^'''^" re-
searches.
last,
—
the
improvement of navigation.
and other
terests
in the
objects are
mind
habits of thought Avhich
we
live as
of a practical people, who,
and modes of eminently
in relief half so grand
lifted up, as
ther, for the ?
9G0
We
A.iv,,Ti-
-winds
knnwiedge ot winds and cur-
Qccan.
action,
utilitarian,
and imposing
ments by which the distant have been
Other
it
in-
promoted thereby, but these
isles
mark
by
their
the age in
do not stand out
as do those achieve-
and marts of the sea
were, and brought closer toge-
convenience of commerce, by
many
days'
sail.
have been told in the foregoing pages how the
blow and the currents flow
in all parts of the
Tliesc control the mariner in his course
kuow how
to stcer his ship
on
this
and
;
to
or that voyage so as
rents.
always to make the most of them,
is
the perfection of
The figures representing the vessels are marked as to show whetlier the prevailing direction the wind be adverse or fair. navigation.
§
9G1
p.iiuiar
When
so of
one looks seaward from the shore, and sees a
ship disappear in the horizon, as she gains an offing on a
voyage
to India,
or the Antipodes perhaps, the
common
EOUTES. idea
that
is
slie
41
bound over a
is
trackless waste, •
1
and the
chapter xvin.
•
•
1
1
chances of another ship, sailing with the same destination the next day, or the next week, coming- up and speaking
her on the "pathless ocean," would, to most minds,
vv'ith
'^
Yet the truth
seem slender indeed.
the winds and
is,
winds ami currents ^le gnidei to the
now becoming
the currents are
that the navio-ator, like the
backwoodsman
maimer.
in the wilder-
enabled
ocean
not indeed upon
"to blaze his way" across the
ness, is ;
be so well understood,
to
literally
trees, as
in the wilderness,
The
upon the wings of the wind.
but
of scientific
results
inquiry have so taught him liow to use these invisible couriers, that they,
with the calm belts of the
him the
as sign-boards to indicate to
tarnino;3,
air,
and
serve forks,
and crossings by the wa}^ Let a ship next week
New York
from
sail
let
many
each other's path ^
times,
"^
before me.
It
:
and the
they will cross ''
Thus a
case in point
to see bound
happens to
They was
Flying Cloud on a recent voyage to California.
New York
California-bound
and
so
other.
But the Archer had
day
that
after
the
sailed
Flying Cloud put to
was the Archer, but without reference
sea,
to each
The Archer, with Wind and Current Charts
alonor the
trades
it
She was runnino- against time,
also.
way across the calms new route, down throusfh the
hand, went blazing her
and
to
the equator
;
in
of Cancer, north-east
the Cloud followed after, cross-
ing the equator upon the
trail of
Thomas
of the Arciier.
Off Cape Horn she came up with him, spoke him, handed luui the latest
for
the Archer and the
are both fine clipper ships, ably commanded.
from
962
caseoftwa vessels
and are almost sm-e
the case of
is
not until the ninth
§
CaUfornia.
each other by the way.
be
to California,
a faster one follow after
New York
dates,
and invited him
to dine
^^''^,j'"J®'
""'"•
— 420 CHAPTER
THE PHYSICAL GEOGRAPHY OF THE
on board the Cloud Archer,
§
963
Result of
thevoy-
" I
was
;
" Avliicli
invitation," says he of the
\
reluctantly coinpelled to decline."
The Flying Cloud finally ranged ahead, made her and disappeared among the clouds that lowered npon the western horizon, being destined to reach her adieus,
.
ages.
SEA.
.
port a week or more in advance of her Cape Horn consort. Though sighting no land from the time of their separation until they gained the offing of
—
or eight thousand miles off
were so nearly the same, IX., they §
This
964
Tiie great
race-
is
San Francisco
the tracks of the
that,
would appear almost
two
six
vessels
being projected on Plate as one.
the great race -course of the ocean
Some
tliousaud milcs in length. *
—some
;
it is fifteen
of the most ° g-lorious
_
course of the ocean.
tnals of ppccd witnessed,
and of prowess that the world ever
among
taken place over
it.
sliips
that
"walk the
Here the modern
waters," have
clipper ship
—
the
work that has ever come from the hands of man has been sent, guided by the lights of science, to contend
noblest
with the elements, to outstrip steam, and astonish the world. §
965
ihtfrTce*^ ofi&52.
The most celebrated and famous off upon this course
been run came Qf 1852,
when
ship-race that has ever :
it
was
in the
autumn
navigators were beginning fully to reap
the benefits of these researches with regard to the winds
and
currents,
and other
geograpliy of the
sea,
ships put to sea from
that four splendid
New
time, tliey presented really a
names of these noble
— the
new
clipper
York, bound for California.
They were ably commanded, and at Sandy Hook, one by one, and Tlie
with the physical
facts connected
as they passed the bar at various intervals of
most magnificent
ships
and
Wild Pigeon, Captain Putnam
spectacle.
their master were, ;
the
John
Gilpin,
;
ROUTES.
Captain Doane
—
Captain Nickels
alas
421
now no more
!
;
the Flying Fish, cHAPTEa
and the Trade "Wind, Captain Webber.
;
know
Like steeds that
were handled
their riders, they
with the most exquisite
'
and judgment, and in such
skill
hands they bounded out upon the "glad waters" most
Each being put upon her mettle from the
gracefully.
was driven, under the seaman's whip and
start,
speed over a com'se that
full
spur, at
would take them three
it
long months to run.
Wild
The Gilpin,
Pigeon
29
October
;
October
sailed
the
Flying Fish,
and the Trade Wind, November
studied
make time
;
9Gn
was the season
It
14.
§
'^^^^''''
Each one was provided with the
for the best passages.
Wind and
12; the John November 1
Current Charts
them attentively
;
;
each one had
evidently
and each one was resolved to
the most of them, and do his best.
All ran against
but the John Gilpin and the Flying Fish for
;
the whole course, and the Wild Pigeon for part of
it,
ran neck and neck, the one against the other, and each against
all.
It wtis a
sweepstake with these ships around
Cape Horn, and through both hemispheres.
Wild Pigeon
led
New
other two out of
tlie
one by seventeen, the other by twenty days.
and chances of the winds seem from the she
fell
gale,
start.
As soon
as she
to
York, the
But luck
her have been against "
had taken her departuie,
into a streak of baffling winds,
and then into a
which she fought against and contended with
week, making but a time of
it
little
in crossing the horse latitudes.
been nineteen days thirteen of
progress the while
them
out,
she had logged
as daj's of calms
and
;
for a
she then had
After having
no
less
baffling
than
winds
§
967
Tiiestmt '"^^'''''
Pigeon."
422
THE PHYSICAL GEOGRAPHY OF THE
had brought her no farther on her way than the
CHAPTER these XVIII. '
parallel of fine
SEA.
26° north in the Atlantic.
run to the equator, crossing
it
between 33° and 34°
She was unavoidably
the thiity-second day out.
w^est,
Thence she had a
west for only two days before, 30° 5° north in an excellent position, she crossed forced to cross
§
968
Testimony of Captain
Pollard.
so far
it
;
—
In proof that the Pigeon had accomplished
that
all
her would permit, gkiU could do, and the chances against ^ y^TQ have the testimony of the barque Hazard, Captain '
'
This vessel, being bound to Rio at the same
Pollard.
The Hazard
time, followed close after the Pigeon.
hand with the charts
old
;
she had already
voyages to Rio, with them for her guide. longest of the six, the
and a half 34°
of which
by compulsion, having
30', also
six
This was the
was twenty-six
line this
time in
crossed 5° north in
But, the fourth day after crossing the equator, she
31°.
was
mean
She crossed the
days.
an
is
made
clear of
Cape
St.
Roque, while the Pigeon cleared
it
in three days.* §
9G9
Better fortiineof
So
far,
had turned up against the
therefore, chances
Pigeon, in spite of the skill displayed
tlie
otiier ves-
by Putnam
as a
na\ngator, for the Gilpin and the Fish came booming
gela.
along, not under better
management, indeed, but with a
better run of luck and fairer courses before them. this stretch
they gained upon her
the Fish ten days
;
so that
In
— the Gilpin seven
now
the abstract logs
and
show
the Pigeon to be but ten days ahead. §
970
Course the of " Fish.
Evidently the Fish was most confident that she had the
lieels
of lier competitors
was proud of
it
;
;
she
felt
her strength, and
she was most anxious for a quick run,
* AccorJiug to the received opinion, this
was impossible.
ROUTES,
and eager withal
for a trial.
423
She dashed down south-
chapter
wardly from Sandy Hook, looking occasionally at the charts
but feeling strong in her sweep of wing, and
;
judgment of her master, she
ti-usting confidently in the
kept, on the average,
noble and fine
crowded on her canvas
trusting quite as
performed
to leeward of
many
Rejoicing in her
the right track. qualities, she
two hundred miles
much
to its
utmost
stretcli,
and
to her heels as to the charts,
the extraordinary feat of crossing, the sixteenth
day out from
New
York, the parallel of 5° north.
The next day she was well south
of 4° north,
and
in
§
971
the doldrums, longitude 34° west.
Now
for Fortune seems to her heels became paralyzed, ' "
have deserted her a while, winds
power
failed him, feared so ;
they were
by them. St.
— ;
at least her master, as the
fovfune seems to '^« " Fisli."
^"''
they gave him his motive
and he was helplessly bafHed
fickle,
The bugbear of a north-west current
off
Cape
Roque^ began to loom up in his imagination, and to
look alarming
upon him
;
;
then the dj*ead of falling to leeward came
chances and luck seemed to conspire against
him, and the mere possibility of finding his fine ship
back-strapped
filled
tlie
mind
of Nickels with evil fore-
He
bodings, and shook his faith in his guide.
doubted
the charts, and committed the mistake of the passage.
The Sailing Directions had cautioned the again and
ward
.
airain,
,
in the equatoiial
would himself engage airs,
navigator,
to fan along to the eastnot to attempt ^
doldrums
;
for,
so doing, he
with baffling
sometimes re-enforced in their weakness by westerly
currents.
But the winds had
failed,
and
so
too,
the
smart captain of the Flying Fish evidently thought, had '
§ 470.
972
tain's
.
by
in a fruitless strife
§
Thecapp'eat mis-
THE PHYSICAL GEOGEAPHY OF THE
424f
'
all
They advise the
Sailing Directions.
CHAPTER the
SEA.
navigator, in
such cases, to dash right across this calm streak, stand
boldly on, take advantage of slants in the wind, ami,
by
make
this device,
easting enough to clear the land.
So, forgetting that the charts are
rience of great
founded on the expe-
numbers who had gone
before him, Nickels,
being tempted, turned a deaf ear to the caution, and flung SiWdy three whole days, and more, of most precious time, dallying in the doldrums. Time
He
lost.
and
Spent four days about the parallel of 3° north,
his ship left the doldi'ums, after this
waste of time,
nearly upon the same meridian at which
entered
she
tliem. §
She was
973
The cap-
r^g
still
in
34;°,
the current keeping her back just
After so great a
fast as slie could fan east.
andac-
very clever master, doubting his
ledseshis enor.
sensible .
Leavinor
of his error.
her
loss,
'-'
tain sees
own judgment, became tlie
spell-bound calms
.
.
behind him, where he had undergone such in his log as follows
:
" I
now
trials,
he wrote
making
regret that, after
so fine a run to 5° north, I did not dash on,
and work
my way
Roque, as
I
to
windward
have experienced
to the
little
northward of
St.
or no westerly set since passing
the equator, while three or four days have been lost in
working
to the eastward,
between the latitude of
8° north, against a strong westerly set;"
have added, §
97i
""
"
with
little
I!!f,' aid.
in the
and
and he might
or no wind."
In three days after this he was clear of J'^'^'^ fi"^®
5°
St.
Roque.
^^ys before him, the Hazard had passed exactly
same
place,
and gained two days on the
Fish,
by
cutting straight across the doldrums, as the Sailing Directions advised
him
to do.
42
ROUTES.
The Wild Pigeon,
crossing the equator also
5
33°, chapter
in
—
-
liad passed along there ten days before, as did also the
Trade Wind twelve days the line to the west of
The
after. 34;°,
latter also crossed
and in four days
after
-j-he
had
-wiid
^'s'^""-"
cleared St. Roque.
But, notwithstanding this loss of three days Fish,
who
so re^-retted
somely retrieved J
it,'
it,
she found herself,
November, alongside of the
on the 2-ith of
Gilpin, her competitor.
parallel of 5° south,
were then both on the
by the
and who afterward so hand-
They
§
976
^''®,„ overhauls t)ie"Gilpin-"
the Gilpin
being thirty-seven miles to the eastward, and of course in
a better position, for the Fish had yet to take advantage of slants, and stand off shore to clear the land.
They had
not seen each other.
The to
be
showed the Gilpin now to be in the best and the subsequent events proved the charts
charts
position,
right,
for thence to
on the Pigeon two
days,
53° south the Gilpin gained
§
977
^^"^(1^"*^^ ci'^^'ts.
and the Pigeon on the Fish
one.
By
dashing through the Straits of Le Maire, the Fish
gained three days on the Gilpin
;
but here Fortune again
deserted the Picjeon, or rather the winds turned against for as she
appeared upon the parallel of Cape Horn,
and was about
to double round, a westerly gale struck
her
;
§
978
^^1'^''/°^''^^^^
"^^''''
her " in the teeth," and kept her at bay for ten days,
making
little
or no way, except alternately fighting in a
calm or buffeting with a
coming
up, "
hand over
gale,
fist,"
while her pursuers were
with
fine
winds and flowing
sheets.
They
finally
overtook her, bringing along with them
propitious gales,
when
all tliree
swept past the Cape, and
§
979
THE PHYSICAL GEOGRAPHY OF THE
426
CHAPTER crossed the parallel of
—
•
d.mbie
"
51° south on the other side of the
Horn," the Fish and the Pigeon one day each ahead
tlie
were doing 980
Prevaiiing winds.
of
GiJpm.
The Pigeon was now, according best position, the Gilpin next, and
§
SE.\.
From
to the charts, in the tlie
Fish last
;
but
all
well.
this parallel to the south-east trades of the Pa-
The
w^inds are from the north-west. q[^q the prcvailino; ^ '-'
position of the Fish, therefore, did not
seem as good as
the others, because she did not have the sea-room in case of an obstinate noith-west gale. §
981
But the winds favoured
On
her.
Positionof crossed the (member the three ships • the vessels on 30th ^[)g Y\sh. recognising the Picreon ';
December.
the
80th of De-
parallel of *
85° south,
the Pigeon saw only J a & o o to " clipper ship," for she could not conceive how the ship
in sight could possibly be the Flying Fish, as that vessel w^as not to leave
she did
:
New York
for
some three weeks
after
the Gilpin was only thirty or forty miles off at
the same time. §
982
Excite-
ment
of
the race,
was now wdng and wing, and had become With fair winds and an open sea, the comi^eexcitinij. i '^ titors had now a clear stretch to the equator of two The
race
i
thousand §
983
five
'
hundred miles before them.
The Flying Fish led the way, the Wild Pigeon pressing her hard, and both dropping the Gilpin quite rapidly, who wa-5 edrjing off to the
westward.
The two foremost reached the equator on the
1 8tii
January, the Fish leading just twenty-five miles in tude,
and crossing in
1 1 2"
* Twenty-five days after that tlie
1
7' ;*
of
lati-
the Pigeon forty miles
Trade Wind clipper came along, San Francisco.
112°, and Jiad a passage of sixteen days thence into
crosse
-u
•o
CO
.-t
1
w»
•*
c
1
«
^
c
— -—
fc:
J;
5
C^O 2
,
"
« *
*
M >
^
I
|lL •
.
1
«
?
_
5C
Jj
„
m
Ol
i
trades
of the
we
the northern hemisphere,
of
way J
of corollary, that the counter•/
'
are not so easily arrested in their
south
''
back in
course, or turned
does in the
it
theii'
as
circuits,
are those of
j'j^^on™'' "^"''^ .
active ">*^
i!i
^"""'
ern tl;an '" *''«
nnrtliern
moreover,
Consequently,
the north.
''
•^
we
should
not,
ii*"'"'-
spliei-e.
either in the trades or the counter-trades of the southern
many
hemisphere, look for as
calms as in those of the
northern systems. holding
Therefore,
logy
following
the
sider
to
this
corollary,
established
as
facts
we in
maj'
con-
:—
That the south-east trade- winds are stronger than the north-east
that
;
the
north-west
counter-trades of the south
—
passage-winds
are stronger
and
—
counter- trades of the north
that the atmospherical
the cir-
in the southern
than
in the northern hemisphere; and, to repeat,
since
culation
is
the wind
moves
southern tlian it
;
more regular and brisk
the
less liable
to interruption in their circuits than the south-west,
it is
§ lOO'J
meteoro-
in its circuits
it
consequently has
in the south
more briskly through the
does through the northern hemispliere, less
time to taiiy or dally by the
way
than in the north; hence the corollary just
But observations also, as well as mathematically drawn inferences, show that calms are much less preva-
stated.
lent in the southern hemisphere.
For
are ample; they are grouped together
tens of thousands,
and Rain
Chai'ts.
V)otIi
this observations
by thousands and
on the Pilot and the Stonu
These charts have not been completed
New
facts
oiogy.
THE PHYSICAL GEOGRAPHY OF THE
44:8
but as far as they Lave
CHAPTER for all parts of tlie ocean,
I_L
this corollary.
These premises being admitted,
1010
^njerence
j.^^^,^^ from^iie yiieceding
beer?
constructed, the facts they utter are in perfect agreement
with the terms of §
SEA.
^,j^
^^ns ladder,
we may
and argue
ascend another the atmo-
that, since
sphere moves more briskly and in more constant streams ^jjj.Q^^orli
racts.
ir>
ei'n
o'eneral its o
than
it
channels of circulation in the south-
does through them in the northern hemi-
sphere; and that, since
calms as often should
it Ije
in
not arrested in
it is
the former as
by
in the latter, neither
it is
turned back by the way, so as to blow in that in which the
gales from the direction opposite to
general circulation carries
The atmosphere, channels
courses
its
it.
in its
movements along
ma}^ be likened,
of circulation,
its
regular
that in
the
southern hemisphere to a fast railway train; that of the northern to a slow. is
The slow
train
may, when
up," run as fast as the fast train, but
to get through so quick
way,
stop,
;
run back, and
therefore, still
it
it is
may
"
steam
not obliged
dally
by
be through in time.
so the fast; it has not time to stop often or to
the
Not
run back
far; neither liave the counter-trades of the south
time to
blow backward; consequently, such being the conditions,
we a
should also expect to find in the extra-tropical south
2:ale
with
eastinor in it
much more seldom than
in the
exti-a-tropical north.
We
shall appeal to observations for the
this conjecture,
and claim
for
it,
also,
correctness of
as presently will
appear, the dignity of an established truth.
TRADE- WINDS OF THE SOUTHERN HEMISPHERE.
449
Observations, with Easting
CilAPTEK xx.
and with Westing i'l them, betu'een corresponding Parallels in North and South Atlantic, ccs shown by the Storm and Rain
nuniber of
Average
Number of
Gales
to the
1000
the
Average gales in
Charts.
North and South tlie
Number
of observations Gales in 1000, with easting ... " " westing... ^Number of observations Between 45° and 50° -j Gales in 1000, with easting ... " " V westing... < Number of observations Between 50° and 55° j Gales in ]000, with easting ... " " '• westing... ^
Between 40° and 45°
-•
^
North.
South.
17,27i 23 66 11,425 2i 106
8756
4816
5169 10 ^7
Ailiintic.
12
82 5548 1
61
24 144
Thus the Storm and Rain Charts show that between the parallels of 40° and 55° there were in the northern liemisphere 33,515 observations, and that for every
observations there were 24 gales vnih. easting, and
In the southern there were 19,473 ob-
with westing.
and
servations,
for every
gales with easting,
Those
1000
of these there were 5
and 80 with westing in them.
for the southern
hemisphere are only for that part
through which vessels pass on their
01 the ocean
1000 105
way
to
and
around Cape Horn. That part of this route which lies between 40° and 55° south, is under the lee of South
fro
America; and Patagonia, that
lies east
almost a rainless region; consequently, to find
of the Andes,
we might
is
expect
more unsteady winds and fewer rains in that part
of the ocean
where the observations
of the tables were
with well out to
for the southern part
made than we should expect
sea, as at
probably be
much
meet
the distance of two or three
thousand miles to the eastward of Patagonia. the contrast presented
to
So that
by the above statement would
greater did our observations extend
entirely across ths South, as they do across the North, Atlantic.
But, as
it is,
the contrast 29
is
very striking.
In
Srher^ of tion in the
i.emi^''"^'^'
THE PHYSICAL GEOGRAPHY OF THE
450 CHAPTER
some
aspects, the meteorological agents of the
spheres, especially those forces
1
RKA.
and the weather,
which control the winds
very much.
differ
two hemi-
wide as to suggest greater regularity
The difference is so and rapidity of cir-
culation on one side of the Equator than on the other.
Numher of Calms to the 1000 Observations, between the Parallels of 30° and 55°, in the North and South Atlantic, and between the Parallels of 30° and 60° in the North and South
Average
Averaiie ^
oai'mr'
Pacific Oceans, as
shown by
the Pilot Charts.
ATLANTIC.
BETWESN THE PARALLELS OF 30"^
and 33°, No. of observations ... Calms to tlie 1000 do. 35° and 40°, No. of observations Calms to the 1000 da 40° and 55°, No. of observations Calms to the 1000 do. 45° and 50°, No. of obseiTations Calms to the 1000 do. 50° and 55°, No. of observations Calms to the 1000 do. 55° and 60°, No. of observations Calms to the 1000 do.
.
Average calms
Periods
to the
1
North.
South.
12,935 46 22,136 37 16,363
40
15,842 26 23,439 24 8,203 27 4,183 25 3,660 16
22,730 34 13,939 31 12,400 53 15,897 35 32,804 32 15,470 43
44,836 35 66,275 23 31,889 23 4,940 21 9,728 17 f 9,111 21
63,050
55.327
113,240
166,829
41
24
39
25
45
000
lo.
1
South.
8,097 38 3,519
Total No. of observations
PACIFIC.
North.
...
Each one of these observations embraces a period of
of the
foregoing observations.
eight hours; the grand total,
if
arranged consecutively,
with the observations drawn cut, each to occupy period separately, would be equal to
373
exhibit several curious and suggestive facts
its
They
years.
concerning
the difference of the atmospherical stability in the
two
hemispheres. §
1011
Causes of the ditfer-
ence of force In
the winds.
If
we would
discover the seat of those forces which
produce this difference in the dynamical status of the two great aerial oceans that envelop our planet, search for
them
in the
we
should
unequal distribution of land and
TEADE-WINDS OF THE SOUTHERN HEMISPHERE. water over
interrupted in their
wooded
chapter
by the continental masses, with snowy mantles in winter, their summer, and their mountain ranges
its circuits
In the other there
is
but
little
land and
the polar side of 40° south especially,
On
is
L
plains, their
sandy deserts in always.
In one the wind
two hemispheres.
tlie
451
if
we
less
snow.
except the
small remnant of this continent that protrudes beyond that parallel in the direction of Cape Horn, there
an
All
island.
There the
is sea.
air is
is
scarcely
never diy;
it is
always in contact with a vapour-giving surface; consequently, the winds there are loaded with moisture, which,
with every change of temperature,
is
either increased
by
further evaporation or diminished by temporary condensa-
The projjelling power of the winds in the southern resides chiefly in the latent heat of ^Ae
tion.
hemisphere
vapour which they suck up from 7
,7
-7
/•
/^
the engirdling sea
on
the soutii-
The Storm and Rain Charts show that within the trade-wind regions of both hemispheres the calm and rain curves are symmetrical the
symmetry
is
also, especially in
gale
and rain
Lieutenant
;
onhT^^'^'
winds of
•
polar side oj Uapricorn.
the
Reason of er propeii-
''
^j;;J;f
that in the extra-tropical regions
between the calm and fog curves; and the southern hemisphere, between the
curves.
Van Gogh,
of the
Dutch navy,
in
an
in- connection be-
terestmg paper on the connection between storms near
Good Hope and the temperature of the sea,^ It is presents a storm and rain chart for that region. founded on 17,810 observations, made by oOO ships, upon wind and weather, between 14° and 32° east and 33° and 37° south.
the Cape of
De Stormen nabij de Kaap de Goede Hoop Temperateur der Zee. '
in
verband beschouwd met de
twecn the temof tiie sea.
;
452
THE PHYSICAL GEOGRAPHY OF THE
By
CHAPTER
that chart the gale and rain curves are so s}Tn-
phenomena of
metrical that the
1
SEA.
extra-tropical
cause and
rains
TJie general storm
effect.
and
present themselves
seas
gales in the
suggestively as
and rain charts of
the Atlantic Ocean, prepared at the National Observatory,
hold out the same idea. explain this § 1012 Cause of
We •
ftict.
ascribe the trade-winds to the latent heat f.
f.
,
Let us examine, expand, and
Set ircc
,
i
i
thecounJincUof"
the equatorial calm -belt.
ernhemu
^^^^
sphere,
c
•
But
oi
which blow with
as
much
which
m
aqueous vapour
what
to
shall
we
ascribe
hemi-
the southern
particularly of
countcr-trades,
sphere,
i
irom the condensation
IS
regularity toward the
Pole as the north-east trades of the Atlantic do toward the Equator
Shall
?
we
say that those winds are drawn
toward the South Pole by
expand and ascend
which causes them to
heat,
in tlie Antarctic regions
somewhat paradoxical
It sounds
?
winds
to say that heat causes the
to blow toward the Poles as well as toward the Equator but, after a little explanation,
few
may
disappear.
It
Averajre
amount
of a
is
facts
by ....
held as an established fact
of
precipita-
and the passing in review
and circumstances, perhaps the paradox
the average
amount
oi
meteorologists that
precipitation
is
m •
i
greater
ii
the
northern than in the southern hemisphere; but
this,
imagine, applies rather to the land than the
On the
polar side of 40",
it
is
then,
gauges to
ments the
and on rare sea.
We
amount of
land of the two hemispheres; and I
It
is
only
now
that ships carry rain-
occasions,
can determine by quantitive measure-
difference in
determination,
I
mostly water in the southern,
mostly land in the northern hemisphere.
and
sea.
imagine,
that
precipitation on
it is tlie
has given
tlie
result of this rise
to
the
—
;
;
TRADE- WINDS OF THE SOUTHERX HEMISPHERE. genei-al
than
remark that the
it
is
rain-fall is greater for the
there
" times"
the
of precipitation,
report
whether
be in the form of rain,
a large corps of observers, rain
omitted in the log; so that in
do not show as "
hail, or
snow,
we may
Still,
in all parts of the sea
called
such
probability the charts
all
rain as there are
This omission, how-
sea.
one hemisphere as in the
ever, is as likely to occur in
other.
is
sometimes, no doubt,
is
many "times" with
times" actually with rain at
Our which,
Among
the charts, and in this discussion, rain.
1
sea
determinations are mostly numerical.
the
it
quantity at
for
observers
by
northern cuAPTta
But we have
southern hemisphere.
for the
few hyetographic measurements
453
assume that
safely
it
rains oftener
than our observations or the rain
charts that are founded on
them
indicate.
With the view of comparing the rains at sea between § 1013 the parallels of 55° and 60°, both in the North and South S'^T"" Atlantic, we have taken from the charts the following H'"^ '*'
: figures o
South
— Observations, 8110
gales,
;
1228
North—
„ 526; „ Gales to the 1000 observations Eains „ „
That
is,
10
for every
hemisphere 9
fall
„
64.
N. 256. N. 121.
why
more copiously at
4.7.
In which
on the average during a
Observations do not
to be a philosophical reason
oftener but
S. 131
in the northern
hemisphere does most water rain at sea?
rains, 1105.
there are in the southern
gales,
and
rains,
S.
;
135; 146 ;
it
tell;
but there seems
should rain not only
sea, especially in
the extra-
tropical regions, in the southern hemisphere, than in those
of the northern.
example, the land
On is
the polar side of 40° north, for
stretched out in continental masses,
Reason
™°'^ 7ai'n
jjj'°"q
t,°an\^,'" *j'^ j;;;'^:'; ^^''"^'^^
4 cHAriTR XX.
of
upon the
down
thirsty
t*°e"enthe "
ft^^d
SEA.
bosom of which, when the
load of moisture, only a portion of
its
taken up again; the rest
dew-
spheres"
THE PHYSICAL GEOGRAPHY OF THE
-t
On
the Springs.
is
drops
air
can be
it
absorbed by the earth to
the polar side of 40° south
we have
^ Water instead of a land surface, and as fast as precipitation takes place there, the ocean replenishes the air with
moisture again.
It
may, consequently, be assumed that a
high dew-point, at
least
one as high as the ocean can
maintain in contact with winds blowing over going from warmer to cooler latitudes
all
the time,
it is
and the
on the polar side of 40° south, whereas on the polar side of 40° north a low dew-point prevails. The rivers to the north of 40° could not, if normal condition of
they were to
make up
the
this
average difference of dew-point between
two hemispheres.
polar sidc of 40° south suggests that
andstoi-m-of curves,
converted into steam, supply vapour enough
The Symmetry of the rain and storm curves on the
Inference
symmetry
all
tlie air
this
it is
the condensation
vapour which, with the liberation of
heat, gives such activity
and regularity to the
its
latent
circulation
of the atmosphere in the other hemisphere.
1014
On
the polar side of 40° south, near Cape Horn, the
gauge of Captains King and Fitzroy showed a
rain-fall of
153.75 inches in 41 days.
There
is
no other place except Clierraponjie where the
precipitation approaches this in amount.
CheiTaponjie
is
a mountain station in India, 4500 feet high, which, in latitude 25° north, acts as a condenser for the monsoons fresh
from the
sea.
But on
45° in the northern hemisphere
American shores
of the
bility that there should
North
polar side of latitude
tlie it
is,
Pacific,
except along the a physical impossi-
be a region of such precipitation
— 455
TRADE-WINDS OF THE SOUTHERN HEMISPHERE. as
King and Fitzroy found on the western
Patagonia
—
ofcuArTEP,
slopes
a physical impossibility, because the peculiar
'
'
.
.
combination of conditions required to produce a Pata-
gonian
rain-fall
is
wanting on the polar
side
45°
of
north.
There
not
is
the North Atlantic water surface
in
causes
why more
enough
to afford vapour for such
an amount of precipita-
rain faiis in the
In the North Pacific the water surface
tion.
may
be
broad and ample enough to afford the vapour, but in neither
of these two northern
sheets
south than nortiu
of water are the
winds continuous enough from the westward to bring in the requisite quantities of vapour from the over,
More-
sea.
if the westerly winds of the extra-tropical north
were as steady and as strong as are those of the south, there
is
lacking in the north
that continental relief
mountain ranges rising abruptly out of the rated from to bring
it
only by lowlands
down
—
sea,
or sepa-
that seems to be necessary
the rain in such floods.
Colonel S3^kes^ quotes the rain-fall of Cherraponjie at Compan-
214 days from April to October, the season of the south-west monsoons. Computing the Cape Horn rains according to the ratio given by King 605.25 inches
for the
,
and Fitzroy
for their
tween the rain
fall a.t
chenaand
in Pa-
41 days of observation, we should
have a rain -fall in Patagonia of 825 inches in 214 days,
amount
or a yearly
Horn
of 1368.7 inches.
rains nor the rains
anywhere at sea on the polar
side of 45° south are periodical.
more copious perhaps abundant at
Now,
at
Neither the Cape
They
are continuous;
some seasons than at
others,
but
all.
considerinof the extent of water-surface on the
»
" Report
of the British Association for 1852," p. 256.
§
1015
THE PHYSICAL GEOGRAPHY OF THE
456 ctrAPTER ^^" ,
polar side of
why,
reason
tlie
SEA,
south-east trade-wind belt,
on these
see
no
engirdling air of
the
parallels,
we
that great watery zone of the south shoiild not, entu'ely
around the earth, be
was that which dropped
as
gonian
tainsoii le
upon the Pata-
had not been
there,
the condensa-
and the consequent precipitation would probably not
tion
ram-
^qq^ ^g gTeat, bccause the conditions at sea are
j^.^^,^
^
this flood
hills.
If those mountains
Effect of
heavily charged with vapour
as
less
apt to produce rain; but the quantity of vapour in the air
would have been none the
which vapour was
less,
borne in the channels of circulation toward the
beins:
Antarctic regions for condensation and the liberation of latent
its
we make,
heat; and
show, no \dolent supposition
we
as
shall proceed to
in attempting to explain
if,
this activity of circulation south of the Equator,
we
sup-
pose a cloud region, a combination of conditions in the Antarctic Circle peculiarly favourable to hea\y and almost incessant precipitation. Effect of
ti^'on"' '^
"'""
But before describing inquire
to
aside
how
conditions,
these
precipitation
far
may
posed cloud region of the south
and regularity
force
to the
let
in
assist
us turn
the
sup-
in giving
winds of the southern hemi-
sphere, §
lOlG
If
we
take a measure, as a cubic
and apply heat
to
it
by means
ties
may
of ice at zero,
of a steady flame that
will give off heat at a uniform rate,
that just enough heat
foot,
and in such quanti-
be imparted to the
we
raise its temperature 1° a miiuite,
shall find that at
the end of 32 minutes the ice will be at 32°. will
now
at 32° for
begin to melt, but
it
140 minutes, when
and all
its
ice to
The
ice
water yviU remain
the ice will have become
TRADE- WINDS OF THE SOUTHERN HEMISPHERE. \^'ater
This 140" of heat, which
at 32°.^
temperature of 140 cubic feet of
raise the
from any point below
32°, has
is
enough to
ice
one degree
become
chaptes L
been rendered latent in the
and
Freeze this water again,
process of liquefaction. this latent heat will
457
sensible heat; for heat
no
more than ponderable matter cannot be annihilated.
But into
after the cubic foot of ice has
if,
water at
32°,
we
been converted
continue the uniform supply of
heat as before, and at the same rate, the water
ture of 2 it wi]l
1
2°
—
will, at
180 minutes more, reach the tempera-
the expiration of
the boiling-point
;
and at
this
temperature
remain for 1030 minutes, notwithstanding the con-
At the
tinuous supply of heat during the interval.
1030 minutes
expiration of this
of boiling heat, the last
drop of water will have been converted into steam
;
but
the temperature of the steam will be that only of the boiling water
thus, in the evaporation of every
:
of water, heat enough cess
to
raise
is
rendered latent during the pro-
the temperature
one degree.
If
this
measure
of
1030 such measures
vapour be now condensed,
latent heat will be set free,
and become
sensible
tins
heat
again.
Hence we perceive that every rain-drop that the sky had in
enough to rain-drops.
come down
its
raise
But
falls
from
process of condensation evolved heat
one degree the temperature of 1030 if,
instead of the liquid state, as rain,
of
evolved by every rain piecipita-
it whether
in the solid state, as hail or snow, then the H^^^^
heat of fluidity, amounting to enough to raise the temperature
iient
140
additional
drops one
degree,
set free.
'
See Espy's "Philosophy of Storms."
is
also
458 CHAPTER
THE PHYSICAL GEOGRAPHY OF THE
SEA.
AVe have in this fact a clue to the violent wind which nsually accompanies hail-storms.
In the hail-storm, con-
the vio-
gelation takes place immediately after condensation, and
which"
so quickly, that the heat evolved during the
accom-
cesses
may
sequently, the upper air has
haii-*^
worms,
two pro-
be considered as of one evolution.
Con-
temperature raised
its
much
higher than could be done by the condensing only.
But
this is
digi-essive
therefore let us take
;
broken thread, and suppose, merely
up the
for illustration, such
a rain-fall as King and Fitzroy encountered in Patagonia to have taken place under the supposed cloud region of
the Antarctic Circle, and to have been hail or snow, instead of rain
among
the
then the total amount of caloric set free
;
clouds,
41
in those
days of such a
flood,
w^ould be enough to raise from freezing to boiling
times
much water
as
as
Antarctic precipitation come
But
fell.
down
if
the
6^
supposed
in the shape of rain,
then the heat set free would be sufficient only to raise
from freezing to boiling about 5| as much water as the flood brought down. §
We
1017
Amount
of
n
i_
have perhaps a better idea of the amount
shall .i
,
titbe
,
heat set
01 hcat that would
condensa-
and cougclation
co°n"ge"a-
vapour as
vapour.
"^'6
'^'^^y
in
make
illustration
tlie
m •
free,
-i
the condensation
the Antarctic regions of as mucli
took to
it
r
set
the Patagonian
by supposing
rain-fixll, if
this rain-fall of
153.75 inches to extend over an area of 1000 square miles, and that it fell as snow or hail. The latent heat set free
among
have been
sufficient
boiling point in area
the clouds during these 41
all
and 884
cold of the Poles,
to
2-aise
from
by
facilitating
daj-s
would
freezing to the
1000 square miles "We now see how the precipitation, is made to
the water in a lake feet in depth.
tlie
TRADE-^\^NDS OF THE SOUTHERN HEMISPHERE.
and develop
react
heat,
to
expand the
459
and give
air
chapter
force to the winds.
__1
Thus we obtain another point of view from which
we may contemplate
in
new
a
the
aspect
1018
§
icebergs
which the antarctic region sends forth in such masses and numbers.
They
are a part of the meteorological machinery of
The
our planet.
offices
most important, and
oh,
which they perform
how
exquisite
as such are
While they are
!
in the process of congelation, the heat of fluidity free,
which, whether
it
is
officas
by
ice-
^'^''
set
be liberated by the freezing of
water at the surface of the earth, or of the rain-drop in the sky, helps in either case to give activity and energy to tlie southern system of circulation,
expanding the
by warming and
air at its place of ascent.
Thus the water, which, by parting with has expended
liquefaction,
its
giving dynamical force to the
steam of the engine
become
It
inert.
is,
;
it
its
heat of
meteorological energy in air, is like
has
exerted
the exhausted
power, and
its
therefore, to be got out of the
way.
In the grand meteorological engine which drives the
wind through and
plant,
icebergs,
climes,
his circuits,
this
and tempers
waste water
it
and borne away by the currents
where the latent heat of
to beast, bird,
collected into antarctic
is
to
more genial
fluidity wliich they dis-
pense to the air in the frigid zone
is
restored,
and where
they are again resolved into water, which, approaching the torrid zone in
cooling streams, again joins in the
work, and helps to cool the air of the trade-winds, to mitigate climate,
and moderate the
gale.
For
if
the
water of southern seas were warmer, evaporation would be greater
j
then the south-east trade-winds would de-
use of
ice-
conveying north to
460
THE PHYSICAL GEOGEAPHY OF THE vapour more
CHAPTER liver '
abundantly to the equatorial calm
make
This would
belts.
SEA.
more
precipitation there
and the additional quantity of heat
set free
copious,
would give Thus
additional velocity to the in-rushing trade-winds. as has already
it is,
been
stated, that, parallel for parallel,
trans-equatorial seas are cooler than cis-equatorial
employed
that icebergs are
is
thus
;
push forward the
to
Effect of
it
on winds,
winds in the polar regions, to hold them back in the equato]-ial
and thus
;
machinery of the " coupled
is
it
we
air,
that,
in contemplating the
how
perceive
icebergs
are
and made to perform the work of a
on,"
regulator, with adjustments the
most
beautiful,
and com-
pensations the most exquisite, in the grand machinery of
the atmosphere. §
With
1019
cai force
wliicli
winds de-
01^6
vapoiir.™
this illustration concerning the
dynamical force
the winds derive from the vapour taken up in
climatc and transported to
"^^^d to sketcli
pro-
thosc physical features, which, being found
in the antarctic circle,
and constant
we may
another,
would be most favourable
precipitation, and,
heavy
to
consequently, to the de-
velopment of a system of aerial circulation peculiarly active, vigorous,
and regular
for the
aqueous hemisphere, as the
may
southern, in contrast with the northern one, ter-trade
the south-
called.
Thcsc vapour-beariug winds, which brought the rains
ThecounWindsor
be
to
•
-r*
Patagonia ^
•
>
1
are
—
t
I
•
wish
•
to
keep p
this
c
reader
vapour-
sphere.
wind's!^
grand system of
-i
aerial
circulation
;
and as
m '
fact
^
mind the counter-trades oi the soutliern As such the}^ have to perform their round
ernhdiiii-
s
—
i\
in
^
the
ihemi-
in the
every
system of circulation there must be some point or place
and commences to must be a place somewhere on
at which motion ceases to be direct,
be retrograde, so
tliere
the surface of our planet where these winds cease to go
TRADE-WINDS OF THE SOUTHERN HEMISPHERE.
and commence
forward, stop,
and
that i^lace
which, could
circle,
-J
'
band or disk within the polar
to be a
it
;
been determined,
locality has not
i-
suppose
I
their return to the north
chapter
all prohahility, tvithin the antarctic
Its precise
reqions. u
but
in
is,
461
ffl S;"rP''"s place of
"'^ "''^'^*
be explored, would be found, like
it
the equatorial calm belts, a place of light airs and calms, of ascending columns of air, a region of clouds
and of
constant precipitation. But, be that as
bearing winds
—
may, the
it
and flow
place has to ascend
grows
it
With
that which
for
In ascending
below.
cool,
which these vapour-
vapour-bearing, because they blow over
such an immense tract of ocean
make room
air
—pour
off as
into this stopping-
an upper current, to
continually flowing
is
expands and grows
it
condensation of
in
cool, and, as
vapour commences.
its
this vast quantities of latent heat,
which converted
the water out at sea into vapour for these winds, are set free in the
upper
There
air.
reacts
it
ascending columns, causing them
and so to
rise
by warming the
further to expand,
still
higher and higher.
This reasoning
suggested not only by the
is
fticts §
and circumstances already stated as well known, but derives
additional
plausibility
for
correctness
by
1020
it
the
low barometer of these regions. In the equatorial calm belts the mean barometric presabout 0.2 inch
sure
is
and
this
dnnmution
perpetual
influx
less
oi
of the
produce the trade-winds. barometric pressure^ 1
vol.
"Maur/e ii.
p. 450.
is
than
it is
pressure air
is
in the trade-winds,
tiicpres-
enough to create a
caim belts
from either Off
0.75 inch
Difference
side,
and
to
Cape Horn the mean less
than in the trade-
Sailing Directions," 6th ed., 1854, p. 692; ditto, 8th ed., 1859,
"** l^^^^^_ ''^'"'^**
462 CHAPTEE
THE PHYSICAL GEOGRAPHY OF THE
wind
This
regions.
is
According to
south.
for the
the
made along
observations
SEA.
parallel say of 57°
mean
of 24)72
—
8"
barometric
that part only of the route to
Australia which lies between the meridians of the Cape
Good Hope and Melbourne, the mean barometric presshown by Lieutenant Van Gogh, of the Dutch navy, to be 0.83 of
sure on the polar side of 42° south has been
inch less than sure
The mean
in the trade-winds.
it is
in this part of the South Indian Ocean
winds with easting in them, 29.8 inches;
winds with westing, 29.6
inches.
pres-
is,
under
ditto,
under
This gives a supposed
sure in
mean pressure in the polar calms of 29.7 inches. To what, if not to the effects of the condensation of vapour bomc by those surcharged winds, and to the immense precipitation in the Austral regions, shall we
latitudes,
ascribc this diminution of the atmospherical pressure in
Diminution of at-
mospiieii-
hio;h
south latitudes
?
It is not so in hisjh north lati-
tudes, except about the Aleutian Islands of the Pacific,
where the sea to windward precipitation
is
also
wide,
frequent, but not so heavy.
is
and where
The steady
flow of "brave" winds toward the south would seem to call for
a combination of physical conditions about their
stopping-place exceedingly favourable to rapid and heavy
and constant
and on the
what
precipitation.
those conditions are.
to perform,
which the
The
rain-fall at Cherraponjie,
slopes of the Patagonian Andes, reminds us
in the
There mountain masses seem
chambers of the uj)per
jet of cold
water does
in the condenser of the engine.
for the
air,
The presence of
not water, about this south polar stopping-place fore,
suggested
mountains are
;
the
office
exhausted steam
is,
land,
there-
for the sea is not so favourable as the
for
aqueous condensation.
'
463
TRADE-WINDS OF THE SOUTHERN HE]MISPHIRE.
By
the
terms
in
which
our proposition has been
465
air is the chief
to the
move
winds of ^^^^ their
throutrh o
channels of circulation, their high speed, great regularity,
And
and consistency of volume. •^
this insight into the °
_
^
we
w^orkings of the wonderful machinery of sea and air
is
research,
and
upon
fro
,
source of "le motive "=« ^'"^^
ofthe south-
inter- tropical seas.
the picture which, after no
little
labour,
much
§
1023
and some thought, the winds have enabled us
draw of
to
^j^
'^'^"^^
comparing together the relative speed of
obtain from
vessels as they sail to
Such
ciiapteu XX.
certain unexplored portions of our planet.
As we have drawn
the picture,
so,
from the workings of
the meteorological machinery of the southern hemisphere,
we judge
it
duced
meteorological in
is
to be.
character,
its
The evidence which has been
we admit
the antarctic regions
be plausible at
—
least.
its
but
;
it
intro-
nature, circumstantial in
shows the idea of land in
—
much land, and high land to Not only so it suggests that a
of
:
group of active volcanoes there w^ould be by no means inconsistent with
the meteorological
phenomena which
we have been investigating. True, volcanoes in a place may not be a meteorological necessity. cannot say that they are
;
such
AVe
yet the force and regularity of
the winds remind us that their presence there would not be inconsistent with we.
may
known
laws.
as well imagine the Antarctic Circle to encompass
land as to encompass water. little
more of
its
We know
ocularly but
topographical features than
those of one of the planets
we
According to these laws,
surely may, without
;
we do
of
but, if they be continental,
any unwarrantable
stretch of the
imagination, relieve the face of naiiu'e there with snow30
Evidence istence of
Ji^ vo'ca-
anurcuc* •'^sions.
THE PHYSICAL GEOGRAPHY OF THE
466
CHAPTER cia^j mountains,
and
SEA.
diversify the landscape with flaming
volcanoes.
None
are
features
of these
with
inconsistent
the
phenomena displayed by the winds. Let us apply to other departments of physics, and seek testimony from
None
other sources of information.
of the evidence to
be gathered there will appear contradictory,
it is
rather in
Southern explorers, as far as they have
Testimony
Corroboration.
piorers.
])enetrated within the Antarctic Circle, tell us of high
lands and mountains of ice of §
and Ross, who went furthest in the distance,
about twicc as large as Eui'ope.
area'ofthe IS
south pole.
;
saw volcanoes bm'ning
The unexplored area around
1024
ttie lines-
all,
South
the
7000
is
This untra veiled region
circular in shape, the circumference of
j^^g^^,g less than
Pole
miles.
Its
which does not have
edges
been
penetrated here and there, and land, wherever seen, has
been high and rugged. Navigators on the voyage from the Cape of Good Hope to Melbourne,
and from Melbourne
to
Cape Horn, scarcely
ever venture, except while passing Cape Horn, to go on the polar side of 55° south. icehergs
thcm.
Tlicsc
may
in tlie
"^
The
fear of icebergs deters
or
be seen there drifting up towards the
^
Bouthein
Equator
in large
numbers and large masses
the year
all
seas. .
round.
I
have encountered them myself as high up as
the parallel of 37° south.
The
belt of ocean that encircles this globe
side of 55° south
found in
all
is
parts of
never free from icebergs. it
the year round.
on the polar
They are of them The thick.
Many
are miles in extent, and hundi-eds of feet
area on the polar side of the 55 th parallel
of south
latitude comprehends a space of 17, 784', 600 square miles.
The nursery
for the bergs, to
fill
such a
field,
must be an
L
4G7
TRADE- WINDS OF THE SOUTHERN HEMISPHERE.
immense one
such a nursery cannot be on the
;
sea, for chapter
icebergs require to be listened firmly to the shore until
they attain
full
They,
size.
way, are loud with evidence
There
is
in their
cliffs
mute
in favour of antarctic shore
may
of deep bays where they
lines of great extent,
formed, and of lofty
therefore,
—
be
whence they may be launched.
another physical circumstance which obtains
Probabu
generally with regard to the distribution of land and
istence of
water over the surface of the earth, and which, as
ticcontu
it
goes,
far as
seems to ^favour the hypothesis of much land
about the South Pole
and that circumstance
;
is
this
:
It
seems to be a physical necessity that land should not be antipodal
to
land.
America and
Asia,
The
belief
is,
Except a small portion of South land
it
applies,
always opposite
is
we have
This law of distribution, so far
in favour of land in the opposite zone.
Finally, geographers are agreed that,
particular facts
water.
to
that on the polar side of 70° north
mostly water, not land. as
is
irrespective of the
and phenomena which we have been con-
sidering, the probabilities are in favour of
an antarctic
continent rather than of an antarctic ocean. "
There
is
now no
doubt,"
says Dr.
Jilek,
in his
"Lehrbuch der Oceanographie," "that around the South Pole there the polar
is
extended a great continent mainly within
circle, since,
although
we do
not
know
it in its
whole extent, yet the portions with which we
have
become acquainted, and the investigations made, furnish sufficient evidences
certainty.
to infer the existence of such with
This southern or antarctic continent advances
furthest northward in a peninsula south-south-east of the
southern end of America, reaching in Trinity Land almost to G2° south latitude.
Outwardly these lands exhibit a
Dr. jiiek's
oinmon on ti,e
s^b.
^'^'^'"
— 468
THE PHYSICAL GEOGRAPHY OF THE
CHAPTER naked, 1
SEA.
rocky, partly volcanic desert, with of
destitute
vegetation,
always
high
rocks
covered with ice and
snow, and so surrounded with ice that
it
is
difficult
or
impossible to examine the coasts very closely "
Discover-
reafthe"'^ south pole.
The
Dumont
principal discoveries of these coasts are (Wilkes), d'Urville,
and Ross (the younger), of
842 followed a
whom
the
100 miles between 72° and 79° south latitude, and 160° and 170° east longitude, to which he gave the name Victoria Land, and j^^|.gj, -j^
2
coast over
on which he discovered a volcano (Erebus) 10,200 feet and 77° south latitude, as
high, in 167° east longitude,
well as another extinct one (Terror)
10,200
and then discovered the magnetic South vatory, WasJdngton, April, »
" Text-book
by Dr. August
of
Oceanography
Ohser-
1859.
for the
Jilek, Yieniia, 1867.
feet high,
Pole."-^
Use of the Imperial Naval Academy,"
1
;
THE ATLANTIC TELEGRAPH.
CHAPTER THE ItsHistorj',
§
1025.— Attempt
to be
The
Atlantic Telegraph
after
having performed for
renewed, 1026.— Causes of Failure, 1027. real Question, 1029.
102S.— The
of Success,
communication only
XXI.
TELEGEAPH OF THE ATLANTIC.
SUB3VIAEINE
—The Probabilities
469
quietly
as
office
its
on
rests
a short time.
its
a
plateau, chapter
channel
The laying
was celebrated with a pomp and circumstance ^ •"
—
of
of
it T,,g^ji.'^
^e'eNew graph.
in
^^'^
York seldom, if ever, witnessed. Though short-lived it was a grand achievement. It demonstrated the possibility of uniting, by a telegraph across the Atlantic, the New World with the Old. Everything that contributed toward the accomplishment
of
achievement
this
possessed of that peculiar interest which attaches to
is
tlie
history of great events. It
is
in
some
sort a result arising
concerning the phj^sics of the it
may
sea,
from these researches
and a short account of
be given here without prejudice to the specialties
of this work.
On
the 1st of September, before an immense assembly
of people in the Crystal Palace of of this telegraphic enterprise
much beauty and and
in
eloquence,
behalf of the
New
rtsuistoiy.
York, the history
was given, in a speech of by David Dudley Field, for
Company
—he
being one of the
original projectors.
In
185
-i,
he and his associates had under consideration
a line from our
own
idea of extending
it
shores to Newfoundland, across the Atlantic
when
the
was suggested
First suit.
thepiaa
THE PHYSICAL GEOGRAPHY OF THE
470
SEA.
CHAPTER
but before they decided upon anything they wrote, said
^f!l
the orator, " to Lieutenant Maury, to inquire about the
Jector'stsk
^nt^lu'd. ry-sopin-
fessor
favour-
j^,
cable,
and consulted Pro-
Morse about the possibility of telegraphing through
On
Their answers were favourable.
-^^
wnich
ion, is
submerging a
practicability of
was decided
able.
It thus appears that this
embodied in the term
receiving '-'
them
"
ahead.' to 'go '^
new department
" Physical
of science,
Geography of the Sea,"
has already contributed to the advancement of one of the grandest and most interesting practical problems which this
age of mind and intelligence has been called on to
demonstrate. steamers to?ay"the "^^^^'
lu the
summer
of 1857, the United States steamer
"Niagara" and H. assigned
by
B.
M. steamer "Agamemnon" were
their respective
governments to the duty of re-
and laying the Submarine Atlantic Cable.
ceiving on board
Other vessels were sent with them as
The plan was,
tenders.
for
pilots, consorts,
Queenstown, Ireland, pay out her cable as far as reach, then pass the
when
it
.spliced,
would
and when that ship would After reaching deep
to Newfoundland.
it
it
end in mid-ocean to the "Agamemnon,"
woidd be
proceed with
and
the "Niagara" to begin at
water, the "Niagara" having paid out about 3 4 4 miles of First foil-
cable, it parted
August 11th, 1857.
This failure post-
uie.
poned further Second at. eir.pt.
trial till
the
summer
of
1
858.
In the Summer of 1858, the same two ^-^^
cable again on board,
ocean,
proceeded
ships,
having
together to mid-
where the two ends were joined, and they then
commenced
to "
pay and go," each toward her own land.
The "Niagara" had 1488 miles of "Afjamemnon" 1477. Total, 2965
cable on board, the miles.
After three unsuccessful attempts to lay the cable, and
— THE ATLANTIC TELEGRAPH. after the loss of
about 400 miles of
it,
47l
the fleet returned
It put to sea again for a last trial, July
to Ireland.
1
chapteis
7,
il
with about 1274 miles of cable on board each of the paying-out
vessels.
They met
in mid-ocean, joined cables,
and
set
out,
the "Niagara" for her terminus in Trinity Bay, and the
"Agamemnon"
for hers in Valentia
Harbour,
—
at 1 P.M.,
July 29th, and successfully landed each vessel her end of
success at last.
the cable on the
otli
after that
were passed through the
messages of congratulation liable
One week
of August.
First
me».
between the Queen of England and the President
of the United States.
The part which the Observatory has played in the history of submarine telegraphy, and of this line between the Old ])art
;
]>ortant
been,
it
it
and useful has
now
feiTiise.
But, whatever
out
commencement here
of
in
blossomed, and fruited, giving benefit charts of the winds secrets snatched
from
its
it
may have
that beautiful system of
1842,
has expanded and
among
its fruits for
and
man's
currents of the sea,
depths.
The
and
present, therefore,
seems to be a proper time for placing on record a state-
ment showing the connection this enterprise,
of the Observatory with
and the part borne
in
it
by each one who
has helped this institution to render good service in such
a
field.
In 1849 the labours of the Observatory in the hydrographical department of
its
duties appear to have attracted
the favourable consideration of Congress of that year a law
was
Ohser.
appears to have been an im-
is
research concerning the physics of the sea, which, having its
tiie
with the
part.
grown
nection of
a quiet and an humble
World and the New,
nevertheless,
the con-
;
for in
March
passed directing the secretary of
THE PHYSICAL GEOGRAPHY OF THE
472 CHAPTER the
" to detail three suitable vessels of the
navy
testing
new
by Lieutenant Maury
to°aid'tbe
^^
t'onsofthe Observa-
navy
vessels of the
in
made
in the course of his investigations
winds and currents of the ocean
f^j, g^jg]^
navy
routes and perfecting the discoveries
BeTbr^
^^^®
SEA.
;
and
to cause the
to co-operate in procuring materials
investigations, in so far as said co-operation
may
not be incompatible with the public interest."
Under
The
this
law the United States schooner "Taney,"
Bchooncr
"Taney"
Lieutenant
make
1849. '
a
J. C.
Slic
series
therefore,
was
Walsh commanding, was sent directed,
among
to sea in
other things, to
make
She was provided, of deep-sea soundings. with fourteen thousand fathoms of steel wire, and
a self-registering deep-sea sounding apparatus,
Mr. Baur, of
New
a plan designed in this fathoms of
made by
York, from drawings and according
line out,
She got a
ofl&ce.
when
it
cast with
to
5700
parted, losing the apparatus.
She then proved unseaworthy, was condemned, and sent back under Longing excited for further iu-
escort.
This reported sounding served to stimulate that longing
,. ,.,.., implaiitcd
which
IS
111
human
the
,.
,
mysteries and the wonders of the great deep this time
,,
breast touching the ;
for
up
to
no systematic attempt had ever been made to
fathom the deep
Sporadic casts of the lead had
sea.
been made here and there in
"
blue water," but though
the reported depths had been great, yet, as with that of the "Taney," there always remained a doubt as to whether
bottom had been reached or to this time
we were
not,
and at what depth.
Up
as ignorant as to the real depths of
the ocean, and the true character of that portion of the solid crust of our planet
are at this of Jupiter.
moment
which constitutes
its
bed, as
we
of the interior of one of the satellites
Using astronomical elements, the mean depth
;
THE ATLANTIC TELEGRAPH.
x
theory, about
My
bad been calculated
ocean
the
of
23
to be, according to chapter '^
miles.
excellent friend, the late
who was
Commodore \Yamngton,
then the chief of the Bureau of Ordnance and
Hydrography, of which the Observatory as
was
the
473
his wont, liberal
plan
deep-sea
of
now
soundings
navy regarded
he was
ready
to
required,
and the law it
a branch, took,
and enliejhtened views touching
secretary of the
such auspices,
is
afford
it
every
itself
was decided
was
The
proposed.
with a lively interest that
the law
enough.
Under
facility
liberal
to inaugurate a regular plan a
of deep-sea sounding for the American navy.
Accord-
repiiar
deep-sea '''^''
formulae were arranged, methods prescribed, and'^°""
ingly,
our men-of-war were furnished with the requisite twine, &;c.,
and commanded
to use every suitable
and convenient
opportunity while at sea to try the depths of
Each
waters.
vessel
was allowed a number
its
deep
of reels of
this twine,
accordincr to her cruisino; m-ound,
containing
ten
each reel
thousand fathoms, weighing about one
hundred pounds.
Under
this order,
Lieutenant William Rogers Taylor, a
the 1st of the "Albany," Captain Piatt, commenced a series of soundings in
and about the gulf of Mexico
;
Captain
Barron, of the "John Adams," ran a line across the Atlantic;
and Captain Walker, of the "Saratoga," got a
cast in the
South Atlantic.
1851
All these soundings required verification; and in
the "Dolphin," Lieutenant-commanding out,
S. P.
under the act of 1849, especially to
observations and experiments.
many casts,
failures,
After
Lee,
assist
many
was
trials,
she at last succeeded in getting
which, being reliable, enabled
me
fitted
me with and as good
to establish a
law
senes ot
com-
474
THE PHYSICAL GEOGRAPHY OF THE
CHAPTER of descent for the '.
plummet, and so prove the soundings
of other vessels.
"made
Lieutenant Lee, having thus
Successor
nant Lee.
SEA,
its
Bud," returned home, bringing with
the egg stand on
him the
best series
of deep-sea soundings that up to that time had ever been
made
;
and they have not been surpassed by any up to
this day.
The "Dolphin" was then placed under the command of H. Berryman, to continue this service.
Lieutenant 0.
With
Lee's plans
sea from
New
and experience
to guide him, he put to
York, October 1852, sounding as he went
as far as the meridian of 40° west,
taken by a
gale,
where he was over-
damaged, and forced into the Tagus
Here he remained
for
December 19 th, and then returned home by the southern route, sounding and lookrepairs.
ing for
With
Anoro-
map
con-
" vigias " as
till
he came.
Lce's soundings in the "Dolphin," together with
thosc already obtained from the regular cruisers in the
the bed of
navy, I was enabled, with the
AHantic
^lyc, to coustruct, in the
Ocean.
fall
of
assistance of Professor
185 2, an orographic map
^^ ^^^ ^^^j ^£ q^^ North Atlantic Ocean, and to give a profile
representing
between
this countiy
a
vertical
section
of
and Europe near the
its
bottom
parallel of 39°
north.
The materials used
The matefor
Ihe^
jnap.
for this
map^ and
deep-sea soundings already mentioned as Taylor, Lee,
profile
were the
made by Walsh,
and Barron, together with others which had
been received from the "Congress," Commodore M'Keever the "Portsmouth," Captain Dornin
;
;
the "Cyane," Captain
Paine; the "St. Louis," Captain Ingraham; the "Plymouth,"
1
See Plates
XIV. aud XV., " Maury's
Sailing Directions," 5th edition.
1
475
THE ATLANTIC TELEGRAPH. Captain Kelly; the
"
Germantown," Captain Knight
"Susquehanna," Captain Inman
;
maps
the chapter
—
These were the
of the "Jamestown," Captain Downing. first
;
and Lieutenant Warley,
of the kind ever attempted for " blue water."
Their object was to show the depressions of the solid crust of our planet helorv, as geographers seek to repre-
sent
The
elevations above the sea-level.i
its
plateau"
there delineated on Plate XIV., very
is
the subsequent deep-sea soundings have shown
This attempt to
map
much
it
as
to be.
out the bottom of the deep sea was
regarded with exceedino: interest by the learned.
Hum-
and most
it opened the freshest boldt gave it high praise ° interesting field that remained to him for contemplation ;
.
in the
Up
domains of to
this time,
however, nothing sea.
and the sounding-line a
was broken
off
so that ball
.
.
when the
t'"^
sub-
jeet.
had ever been
The plummet was a canbit of small twine which
cannon-ball reached the bottom,
and twine remained behind
;
consequently,
every cast of the deep-sea plummet involved the a shot and of as
"i™teiest in
science.
brought up from the deep non-ball,
.
" telegraphic
much twine
as it
loss
of
took to reach the
was desirable to bring up soundings, not only that we might learn what the bottom and bed of the ocean were made of, but that we might know of a verity and have the proof that the bottom had been bottom.
It
reached.
Under these circumstances, the attention of Lieutenant J. M. Brooke, who was at the time stationed at the Observatory, was called to the subject, when he made, for bringing up specimens froiri the bottom, the beautiful and
contriv-
bringing
m^ensfrom "'"
of tbe
ocean.
'See p. 239, 240, 5th ed. "Maury's Sailing Directions," printed by C. Alexander, Washington, and published in February 1853.
;
THE PHYSICAL GEOGRAPHY OF THE
476
known
CHAPTER simple contrivance XXI.
apparatus.
When the
,
ordered to sea to Ob-
as " Brooke's deep-sea sounding
,)
,
^. The ..^ "DolP'"""
returned from the "Dolphin" i
Tacnis, which she °
did in March 1858, arrivinor " at Norfolk on the 7th of to sea again under Berry\^\^^\^ nionth, shc was ordered
tain speci-
_
_
uieus.
SEA.
man, to
assist still further " in perfecting the discoveries
made by Lieutenant Maury
might procure specimens of the bottom,
first
first
time that
time
was put on board any
it
was used was
it
midshipman on board that
Mitchell, then a
boat;
it
all
occupied
since Lee's time,
six
hours.
fathoms, and the rod came up,
The
1853, in
by
brig.
The depth was its
was
J. G.
This
was made from a
2000
arming loaded with
This promising young
precious trophies.
this
vessel.
at 1.20 P.M., July 7,
latitude 5 4° 17' north, longitude 20° 33' west,
sounding, as were
that
this apparatus
was put on board the "Dolphin;" and
of Brooke
the
And
and currents of the ocean."
tion of the winds I
in the course of his investiga-
officer
made
every deep-sea sounding that was made in the "Dolphin"
during that The
first
obtained,
save one only, and to him belongs the
cruise,
liouour of bringing
up the
first
specimen that was ever
obtained from the bottom of the deep sea.
during this
but the
cruise, several
first
Subsequently,
other specimens were obtained
was described by Mitchell
as " a fine chalky
clay."
The "Dolphin" returned
in
November 1853.
Her
soundings during these two cruises with Brooke's apparatus were
first
published in the sixth edition of " Sail-
ing Directions," March 1854.
The specimens from the
bottom were forwarded to the Observatory, and by sent to that charming Bailey, of
West
man
me
of science, the late Professor
Point, for examination under his micro-
—
;
477
THE ATLANTIC TELEGRAPH.
He examined
scope.
and found those specimens
tliem,
"
from the bottom of the great deep not to have tide of
sand or gravel mixed were when
'par-
forces at play
is
\
mensToiu
unworn and un-
l^eoceaa'
alive.
T-'nirmt
This discovery of the miscroscope at once suggested the idea that there
'.
but to be mites
ivith tliern,"
of sea-shells, perfect in form, and as triturated as they
a
cHArrER
T
Wf West
ll"
,.. ,1
W.M.W.
73?
mw.
.™
174 SOS
Xlf.W.
,n»=
..
5-Notih
...t:l
1 1
I )5Tasr.
H 0-
1
u5-E.
.
.
OULI^'
STllEAM
AND
DRIFT.
KX P
a
Thf place
_
I't'
I,
FINITE
A \AT
I CJ
5
..r
%
>v>^>'
.
San Ft'Uirtaro aJ'tjer the wre^k aJtojutoned Jan '>
the
//.
o _ Where rf/ir tvtw aM Computed (u»uU oV Drift
WiJfre the settivhint/ vtsufl
e .v.y.x
*
Thf^hot
JitreaJe.T
wus direeied
of Fio.
-J)ire£tum of Flow
and
PUn*, not tteady in ani/
to
Inok for
--tc'lS"'. '•.:•"
A O/'if'
dire*-tioit
P-
fi
\
' 1
^..'1
.y:i
'i;.,,
I
NEISOK t
SOJiS.
lOSBOX.XDrNBTJaGH i NIW
VOELK.
VI.
r
„
I
(
A
GEOLOGICAL AGENCY OF THE WItfDS
PIATE
F.xpl.'uiafinu.
The
.ih,t/'i i.»
.m/>f>os,-il
hi-
/v.t an
the shoilint) C, vhrn' it
ttitit
.
/«'
7/1 -•
thr nil/i
up: Thr nands
(iiAvn
srvroRX.
VR.
U/.\.'>S
IXI)
NOITHS
PL.riK vin
rr^^^Fr^^^ S-^ .i
^^^R=7^
# ^*^^^ 5 5» '^
EXI'LASATIOX .-.'
"v>^.
.V,„lJ,
Saul Tra.l^^
.¥„„//. Jf.ul
Tvirffs
-^r^:
>-^ V^'
I'rrraiUntj WfiStwartU^/ J\'m/tg
v>A M ^-'"^Y\
^
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>-^-