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Chapter I
ST. JAGO, IN THE CAPE DE VERDE ARCHIPELAGO.
Rocks of the lowest series.
A calcareous sedimentary deposit, with recent shells, altered by the
contact of superincumbent lava, its horizontality and extent.
Subsequent volcanic eruptions, associated with calcareous matter in an
earthy and fibrous form, and often enclosed within the separate cells of
the scoriae.
Ancient and obliterated orifices of eruption of small size.
Difficulty of tracing over a bare plain recent streams of lava.
Inland hills of more ancient volcanic rock.
Decomposed olivine in large masses.
Feldspathic rocks beneath the upper crystalline basaltic strata.
Uniform structure and form of the more ancient volcanic hills.
Form of the valleys near the coast.
Conglomerate now forming on the sea beach.
(FIGURE 1: MAP 1: PART OF ST. JAGO, ONE OF THE CAPE DE VERDE ISLANDS.)
The island of St. Jago extends in a N.N.W. and S.S.E. direction, thirty
miles in length by about twelve in breadth. My observations, made during
two visits, were confined to the southern portion within the distance of a
few leagues from Porto Praya. The country, viewed from the sea, presents a
varied outline: smooth conical hills of a reddish colour (like Red Hill in
Figure 1 (Map 1). (The outline of the coast, the position of the villages,
streamlets, and of most of the hills in this woodcut, are copied from the
chart made on board H.M.S. "Leven." The square-topped hills (A, B, C, etc.)
are put in merely by eye, to illustrate my description.)), and others less
regular, flat-topped, and of a blackish colour (like A, B, C,) rise from
successive, step-formed plains of lava. At a distance, a chain of
mountains, many thousand feet in height, traverses the interior of the
island. There is no active volcano in St. Jago, and only one in the group,
namely at Fogo. The island since being inhabited has not suffered from
destructive earthquakes.
The lowest rocks exposed on the coast near Porto Praya, are highly
crystalline and compact; they appear to be of ancient, submarine, volcanic
origin; they are unconformably covered by a thin, irregular, calcareous
deposit, abounding with shells of a late tertiary period; and this again is
capped by a wide sheet of basaltic lava, which has flowed in successive
streams from the interior of the island, between the square-topped hills
marked A, B, C, etc. Still more recent streams of lava have been erupted
from the scattered cones, such as Red and Signal Post Hills. The upper
strata of the square-topped hills are intimately related in mineralogical
composition, and in other respects, with the lowest series of the coast-
rocks, with which they seem to be continuous.
MINERALOGICAL DESCRIPTION OF THE ROCKS OF THE LOWEST SERIES.
These rocks possess an extremely varying character; they consist of black,
brown, and grey, compact, basaltic bases, with numerous crystals of augite,
hornblende, olivine, mica, and sometimes glassy feldspar. A common variety
is almost entirely composed of crystals of augite with olivine. Mica, it is
known, seldom occurs where augite abounds; nor probably does the present
case offer a real exception, for the mica (at least in my best
characterised specimen, in which one nodule of this mineral is nearly half
an inch in length) is as perfectly rounded as a pebble in a conglomerate,
and evidently has not been crystallised in the base, in which it is now
enclosed, but has proceeded from the fusion of some pre-existing rock.
These compact lavas alternate with tuffs, amygdaloids, and wacke, and in
some places with coarse conglomerate. Some of the argillaceous wackes are
of a dark green colour, others, pale yellowish-green, and others nearly
white; I was surprised to find that some of the latter varieties, even
where whitest, fused into a jet black enamel, whilst some of the green
varieties afforded only a pale gray bead. Numerous dikes, consisting
chiefly of highly compact augitic rocks, and of gray amygdaloidal
varieties, intersect the strata, which have in several places been
dislocated with considerable violence, and thrown into highly inclined
positions. One line of disturbance crosses the northern end of Quail Island
(an islet in the Bay of Porto Praya), and can be followed to the mainland.
These disturbances took place before the deposition of the recent
sedimentary bed; and the surface, also, had previously been denuded to a
great extent, as is shown by many truncated dikes.
DESCRIPTION OF THE CALCAREOUS DEPOSIT OVERLYING THE FOREGOING VOLCANIC
ROCKS.
This stratum is very conspicuous from its white colour, and from the
extreme regularity with which it ranges in a horizontal line for some miles
along the coast. Its average height above the sea, measured from the upper
line of junction with the superincumbent basaltic lava, is about sixty
feet; and its thickness, although varying much from the inequalities of the
underlying formation, may be estimated at about twenty feet. It consists of
quite white calcareous matter, partly composed of organic debris, and
partly of a substance which may be aptly compared in appearance with
mortar. Fragments of rock and pebbles are scattered throughout this bed,
often forming, especially in the lower part, a conglomerate. Many of the
fragments of rock are whitewashed with a thin coating of calcareous matter.
At Quail Island, the calcareous deposit is replaced in its lowest part by a
soft, brown, earthy tuff, full of Turritellae; this is covered by a bed of
pebbles, passing into sandstone, and mixed with fragments of echini, claws
of crabs, and shells; the oyster-shells still adhering to the rock on which
they grew. Numerous white balls appearing like pisolitic concretions, from
the size of a walnut to that of an apple, are embedded in this deposit;
they usually have a small pebble in their centres. Although so like
concretions, a close examination convinced me that they were Nulliporae,
retaining their proper forms, but with their surfaces slightly abraded:
these bodies (plants as they are now generally considered to be) exhibit
under a microscope of ordinary power, no traces of organisation in their
internal structure. Mr. George R. Sowerby has been so good as to examine
the shells which I collected: there are fourteen species in a sufficiently
perfect condition for their characters to be made out with some degree of
certainty, and four which can be referred only to their genera. Of the
fourteen shells, of which a list is given in the Appendix, eleven are
recent species; one, though undescribed, is perhaps identical with a
species which I found living in the harbour of Porto Praya; the two
remaining species are unknown, and have been described by Mr. Sowerby.
Until the shells of this Archipelago and of the neighbouring coasts are
better known, it would be rash to assert that even these two latter shells
are extinct. The number of species which certainly belong to existing
kinds, although few in number, are sufficient to show that the deposit
belongs to a late tertiary period. From its mineralogical character, from
the number and size of the embedded fragments, and from the abundance of
Patellae, and other littoral shells, it is evident that the whole was
accumulated in a shallow sea, near an ancient coast-line.
EFFECTS PRODUCED BY THE FLOWING OF THE SUPERINCUMBENT BASALTIC LAVA OVER
THE CALCAREOUS DEPOSIT.
These effects are very curious. The calcareous matter is altered to the
depth of about a foot beneath the line of junction; and a most perfect
gradation can be traced, from loosely aggregated, small, particles of
shells, corallines, and Nulliporae, into a rock, in which not a trace of
mechanical origin can be discovered, even with a microscope. Where the
metamorphic change has been greatest, two varieties occur. The first is a
hard, compact, white, fine-grained rock, striped with a few parallel lines
of black volcanic particles, and resembling a sandstone, but which, upon
close examination, is seen to be crystallised throughout, with the
cleavages so perfect that they can be readily measured by the reflecting
goniometer. In specimens, where the change has been less complete, when
moistened and examined under a strong lens, the most interesting gradation
can be traced, some of the rounded particles retaining their proper forms,
and others insensibly melting into the granulo-crystalline paste. The
weathered surface of this stone, as is so frequently the case with ordinary
limestones, assumes a brick-red colour.
The second metamorphosed variety is likewise a hard rock, but without any
crystalline structure. It consists of a white, opaque, compact, calcareous
stone, thickly mottled with rounded, though regular, spots of a soft,
earthy, ochraceous substance. This earthy matter is of a pale yellowish-
brown colour, and appears to be a mixture of carbonate of lime with iron;
it effervesces with acids, is infusible, but blackens under the blowpipe,
and becomes magnetic. The rounded form of the minute patches of earthy
substance, and the steps in the progress of their perfect formation, which
can be followed in a suit of specimens, clearly show that they are due
either to some power of aggregation in the earthy particles amongst
themselves, or more probably to a strong attraction between the atoms of
the carbonate of line, and consequently to the segregation of the earthy
extraneous matter. I was much interested by this fact, because I have often
seen quartz rocks (for instance, in the Falkland Islands, and in the lower
Silurian strata of the Stiper-stones in Shropshire), mottled in a precisely
analogous manner, with little spots of a white, earthy substance (earthy
feldspar?); and these rocks, there was good reason to suppose, had
undergone the action of heat,--a view which thus receives confirmation.
This spotted structure may possibly afford some indication in
distinguishing those formations of quartz, which owe their present
structure to igneous action, from those produced by the agency of water
alone; a source of doubt, which I should think from my own experience, that
most geologists, when examining arenaceo-quartzose districts must have
experienced.
The lowest and most scoriaceous part of the lava, in rolling over the
sedimentary deposit at the bottom of the sea, has caught up large
quantities of calcareous matter, which now forms a snow-white, highly
crystalline basis to a breccia, including small pieces of black, glossy
scoriae. A little above this, where the lime is less abundant, and the lava
more compact, numerous little balls, composed of spicula of calcareous
spar, radiating from common centres, occupy the interstices. In one part of
Quail Island, the lime has thus been crystallised by the heat of the
superincumbent lava, where it is only thirteen feet in thickness; nor had
the lava been originally thicker, and since reduced by degradation, as
could be told from the degree of cellularity of its surface. I have already
observed that the sea must have been shallow in which the calcareous
deposit was accumulated. In this case, therefore, the carbonic acid gas has
been retained under a pressure, insignificant compared with that (a column
of water, 1,708 feet in height) originally supposed by Sir James Hall to be
requisite for this end: but since his experiments, it has been discovered
that pressure has less to do with the retention of carbonic acid gas, than
the nature of the circumjacent atmosphere; and hence, as is stated to be
the case by Mr. Faraday, masses of limestone are sometimes fused and
crystallised even in common limekilns. (I am much indebted to Mr. E.W.
Brayley in having given me the following references to papers on this
subject: Faraday in the "Edinburgh New Philosophical Journal" volume 15
page 398; Gay-Lussac in "Annales de Chem. et Phys." tome 63 page 219
translated in the "London and Edinburgh Philosophical Magazine" volume 10
page 496.) Carbonate of lime can be heated to almost any degree, according
to Faraday, in an atmosphere of carbonic acid gas, without being
decomposed; and Gay-Lussac found that fragments of limestone, placed in a
tube and heated to a degree, not sufficient by itself to cause their
decomposition, yet immediately evolved their carbonic acid, when a stream
of common air or steam was passed over them: Gay-Lussac attributes this to
the mechanical displacement of the nascent carbonic acid gas. The
calcareous matter beneath the lava, and especially that forming the
crystalline spicula between the interstices of the scoriae, although heated
in an atmosphere probably composed chiefly of steam, could not have been
subjected to the effects of a passing stream; and hence it is, perhaps,
that they have retained their carbonic acid, under a small amount of
pressure.
The fragments of scoriae, embedded in the crystalline calcareous basis, are
of a jet black colour, with a glossy fracture like pitchstone. Their
surfaces, however, are coated with a layer of a reddish-orange, translucent
substance, which can easily be scratched with a knife; hence they appear as
if overlaid by a thin layer of rosin. Some of the smaller fragments are
partially changed throughout into this substance: a change which appears
quite different from ordinary decomposition. At the Galapagos Archipelago
(as will be described in a future chapter), great beds are formed of
volcanic ashes and particles of scoriae, which have undergone a closely
similar change.
THE EXTENT AND HORIZONTALITY OF THE CALCAREOUS STRATUM.
(FIGURE 2: SIGNAL POST HILL. (Section with A low and C high.)
A.--Ancient volcanic rocks.
B.--Calcareous stratum.
C.--Upper basaltic lava.)
The upper line of surface of the calcareous stratum, which is so
conspicuous from being quite white and so nearly horizontal, ranges for
miles along the coast, at the height of about sixty feet above the sea. The
sheet of basalt, by which it is capped, is on an average eighty feet in
thickness. Westward of Porto Praya beyond Red Hill, the white stratum with
the superincumbent basalt is covered up by more recent streams. Northward
of Signal Post Hill, I could follow it with my eye, trending away for
several miles along the sea cliffs. The distance thus observed is about
seven miles; but I cannot doubt from its regularity that it extends much
farther. In some ravines at right angles to the coast, it is seen gently
dipping towards the sea, probably with the same inclination as when
deposited round the ancient shores of the island. I found only one inland
section, namely, at the base of the hill marked A, where, at the height of
some hundred feet, this bed was exposed; it here rested on the usual
compact augitic rock associated with wacke, and was covered by the
widespread sheet of modern basaltic lava. Some exceptions occur to the
horizontality of the white stratum: at Quail Island, its upper surface is
only forty feet above the level of the sea; here also the capping of lava
is only between twelve and fifteen feet in thickness; on the other hand, at
the north-east side of Porto Praya harbour, the calcareous stratum, as well
as the rock on which it rests, attain a height above the average level: the
inequality of level in these two cases is not, as I believe, owing to
unequal elevation, but to original irregularities at the bottom of the sea.
Of this fact, at Quail Island, there was clear evidence in the calcareous
deposit being in one part of much greater than the average thickness, and
in another part being entirely absent; in this latter case, the modern
basaltic lavas rested directly on those of more ancient origin.
Under Signal Post Hill, the white stratum dips into the sea in a remarkable
manner. This hill is conical, 450 feet in height, and retains some traces
of having had a crateriform structure; it is composed chiefly of matter
erupted posteriorly to the elevation of the great basaltic plain, but
partly of lava of apparently submarine origin and of considerable
antiquity. The surrounding plain, as well as the eastern flank of this
hill, has been worn into steep precipices, overhanging the sea. In these
precipices, the white calcareous stratum may be seen, at the height of
about seventy feet above the beach, running for some miles both northward
and southward of the hill, in a line appearing to be perfectly horizontal;
but for a space of a quarter of a mile directly under the hill, it dips
into the sea and disappears. On the south side the dip is gradual, on the
north side it is more abrupt, as is shown in Figure 2. As neither the
calcareous stratum, nor the superincumbent basaltic lava (as far as the
latter can be distinguished from the more modern ejections), appears to
thicken as it dips, I infer that these strata were not originally
accumulated in a trough, the centre of which afterwards became a point of
eruption; but that they have subsequently been disturbed and bent. We may
suppose either that Signal Post Hill subsided after its elevation with the
surrounding country, or that it never was uplifted to the same height with
it. This latter seems to me the most probable alternative, for during the
slow and equable elevation of this portion of the island, the subterranean
motive power, from expending part of its force in repeatedly erupting
volcanic matter from beneath this point, would, it is likely, have less
force to uplift it. Something of the same kind seems to have occurred near
Red Hill, for when tracing upwards the naked streams of lava from near
Porto Praya towards the interior of the island, I was strongly induced to
suspect, that since the lava had flowed, the slope of the land had been
slightly modified, either by a small subsidence near Red Hill, or by that
portion of the plain having been uplifted to a less height during the
elevation of the whole area.
THE BASALTIC LAVA, SUPERINCUMBENT ON THE CALCAREOUS DEPOSIT.
This lava is of a pale grey colour, fusing into a black enamel; its
fracture is rather earthy and concretionary; it contains olivine in small
grains. The central parts of the mass are compact, or at most crenulated
with a few minute cavities, and are often columnar. At Quail Island this
structure was assumed in a striking manner; the lava in one part being
divided into horizontal laminae, which became in another part split by
vertical fissures into five-sided plates; and these again, being piled on
each other, insensibly became soldered together, forming fine symmetrical
columns. The lower surface of the lava is vesicular, but sometimes only to
the thickness of a few inches; the upper surface, which is likewise
vesicular, is divided into balls, frequently as much as three feet in
diameter, made up of concentric layers. The mass is composed of more than
one stream; its total thickness being, on an average, about eighty feet:
the lower portion has certainly flowed beneath the sea, and probably
likewise the upper portion. The chief part of this lava has flowed from the
central districts, between the hills marked A, B, C, etc., in the woodcut-
map. The surface of the country, near the coast, is level and barren;
towards the interior, the land rises by successive terraces, of which four,
when viewed from a distance, could be distinctly counted.
VOLCANIC ERUPTIONS SUBSEQUENT TO THE ELEVATION OF THE COASTLAND; THE
EJECTED MATTER ASSOCIATED WITH EARTHY LIME.
These recent lavas have proceeded from those scattered, conical, reddish-
coloured hills, which rise abruptly from the plain-country near the coast.
I ascended some of them, but will describe only one, namely, RED HILL,
which may serve as a type of its class, and is remarkable in some especial
respects. Its height is about six hundred feet; it is composed of bright
red, highly scoriaceous rock of a basaltic nature; on one side of its
summit there is a hollow, probably the last remnant of a crater. Several of
the other hills of this class, judging from their external forms, are
surmounted by much more perfect craters. When sailing along the coast, it
was evident that a considerable body of lava had flowed from Red Hill, over
a line of cliff about one hundred and twenty feet in height, into the sea:
this line of cliff is continuous with that forming the coast, and bounding
the plain on both sides of this hill; these streams, therefore, were
erupted, after the formation of the coast-cliffs, from Red Hill, when it
must have stood, as it now does, above the level of the sea. This
conclusion accords with the highly scoriaceous condition of all the rock on
it, appearing to be of subaerial formation: and this is important, as there
are some beds of calcareous matter near its summit, which might, at a hasty
glance, have been mistaken for a submarine deposit. These beds consist of
white, earthy, carbonate of lime, extremely friable so as to be crushed
with the least pressure; the most compact specimens not resisting the
strength of the fingers. Some of the masses are as white as quicklime, and
appear absolutely pure; but on examining them with a lens, minute particles
of scoriae can always be seen, and I could find none which, when dissolved
in acids, did not leave a residue of this nature. It is, moreover,
difficult to find a particle of the lime which does not change colour under
the blowpipe, most of them even becoming glazed. The scoriaceous fragments
and the calcareous matter are associated in the most irregular manner,
sometimes in obscure beds, but more generally as a confused breccia, the
lime in some parts and the scoriae in others being most abundant. Sir H. De
la Beche has been so kind as to have some of the purest specimens analysed,
with a view to discover, considering their volcanic origin, whether they
contained much magnesia; but only a small portion was found, such as is
present in most limestones.
Fragments of the scoriae embedded in the calcareous mass, when broken,
exhibit many of their cells lined and partly filled with a white, delicate,
excessively fragile, moss-like, or rather conferva-like, reticulation of
carbonate of lime. These fibres, examined under a lens of one-tenth of an
inch focal distance, appear cylindrical; they are rather above one-
thousandth of an inch in diameter; they are either simply branched, or more
commonly united into an irregular mass of network, with the meshes of very
unequal sizes and of unequal numbers of sides. Some of the fibres are
thickly covered with extremely minute spicula, occasionally aggregated into
little tuffs; and hence they have a hairy appearance. These spicula are of
the same diameter throughout their length; they are easily detached, so
that the object-glass of the microscope soon becomes scattered over with
them. Within the cells of many fragments of the scoria, the lime exhibits
this fibrous structure, but generally in a less perfect degree. These cells
do not appear to be connected with one another. There can be no doubt, as
will presently be shown, that the lime was erupted, mingled with the lava
in its fluid state, and therefore I have thought it worth while to describe
minutely this curious fibrous structure, of which I know nothing analogous.
From the earthy condition of the fibres, this structure does not appear to
be related to crystallisation.
Other fragments of the scoriaceous rock from this hill, when broken, are
often seen marked with short and irregular white streaks, which are owing
to a row of separate cells being partly, or quite, filled with white
calcareous powder. This structure immediately reminded me of the appearance
in badly kneaded dough, of balls and drawn-out streaks of flour, which have
remained unmixed with the paste; and I cannot doubt that small masses of
the lime, in the same manner remaining unmixed with the fluid lava, have
been drawn out when the whole was in motion. I carefully examined, by
trituration and solution in acids, pieces of the scoriae, taken from within
half-an-inch of those cells which were filled with the calcareous powder,
and they did not contain an atom of free lime. It is obvious that the lava
and lime have on a large scale been very imperfectly mingled; and where
small portions of the lime have been entangled within a piece of the viscid
lava, the cause of their now occupying, in the form of a powder or of a
fibrous reticulation, the vesicular cavities, is, I think, evidently due to
the confined gases having most readily expanded at the points where the
incoherent lime rendered the lava less adhesive.
A mile eastward of the town of Praya, there is a steep-sided gorge, about
one hundred and fifty yards in width, cutting through the basaltic plain
and underlying beds, but since filled up by a stream of more modern lava.
This lava is dark grey, and in most parts compact and rudely columnar; but
at a little distance from the coast, it includes in an irregular manner a
brecciated mass of red scoriae mingled with a considerable quantity of
white, friable, and in some parts, nearly pure earthy lime, like that on
the summit of Red Hill. This lava, with its entangled lime, has certainly
flowed in the form of a regular stream; and, judging from the shape of the
gorge, towards which the drainage of the country (feeble though it now be)
still is directed, and from the appearance of the bed of loose water-worn
blocks with their interstices unfilled, like those in the bed of a torrent,
on which the lava rests, we may conclude that the stream was of subaerial
origin. I was unable to trace it to its source, but, from its direction, it
seemed to have come from Signal Post Hill, distant one mile and a quarter,
which, like Red Hill, has been a point of eruption subsequent to the
elevation of the great basaltic plain. It accords with this view, that I
found on Signal Post Hill, a mass of earthy, calcareous matter of the same
nature, mingled with scoriae. I may here observe that part of the
calcareous matter forming the horizontal sedimentary bed, especially the
finer matter with which the embedded fragments of rock are whitewashed, has
probably been derived from similar volcanic eruptions, as well as from
triturated organic remains: the underlying, ancient, crystalline rocks,
also, are associated with much carbonate of lime, filling amygdaloidal
cavities, and forming irregular masses, the nature of which latter I was
unable to understand.
Considering the abundance of earthy lime near the summit of Red Hill, a
volcanic cone six hundred feet in height, of subaerial growth,--considering
the intimate manner in which minute particles and large masses of scoriae
are embedded in the masses of nearly pure lime, and on the other hand, the
manner in which small kernels and streaks of the calcareous powder are
included in solid pieces of the scoriae,--considering, also, the similar
occurrence of lime and scoriae within a stream of lava, also supposed, with
good reason, to have been of modern subaerial origin, and to have flowed
from a hill, where earthy lime also occurs: I think, considering these
facts, there can be no doubt that the lime has been erupted, mingled with
the molten lava. I am not aware that any similar case has been described:
it appears to me an interesting one, inasmuch as most geologists must have
speculated on the probable effects of a volcanic focus, bursting through
deep-seated beds of different mineralogical composition. The great
abundance of free silex in the trachytes of some countries (as described by
Beudant in Hungary, and by P. Scrope in the Panza Islands), perhaps solves
the inquiry with respect to deep-seated beds of quartz; and we probably
here see it answered, where the volcanic action has invaded subjacent
masses of limestone. One is naturally led to conjecture in what state the
now earthy carbonate of lime existed, when ejected with the intensely
heated lava: from the extreme cellularity of the scoriae on Red Hill, the
pressure cannot have been great, and as most volcanic eruptions are
accompanied by the emission of large quantities of steam and other gases,
we here have the most favourable conditions, according to the views at
present entertained by chemists, for the expulsion of the carbonic acid.
(Whilst deep beneath the surface, the carbonate of lime was, I presume, in
a fluid state. Hutton, it is known, thought that all amygdaloids were
produced by drops of molten limestone floating in the trap, like oil in
water: this no doubt is erroneous, but if the matter forming the summit of
Red Hill had been cooled under the pressure of a moderately deep sea, or
within the walls of a dike, we should, in all probability, have had a trap
rock associated with large masses of compact, crystalline, calcareous spar,
which, according to the views entertained by many geologists, would have
been wrongly attributed to subsequent infiltration.) Has the slow re-
absorption of this gas, it may be asked, given to the lime in the cells of
the lava, that peculiar fibrous structure, like that of an efflorescing
salt? Finally, I may remark on the great contrast in appearance between
this earthy lime, which must have been heated in a free atmosphere of steam
and other gases, while the white, crystalline, calcareous spar, produced by
a single thin sheet of lava (as at Quail Island) rolling over similar
earthy lime and the debris of organic remains, at the bottom of a shallow
sea.
SIGNAL POST HILL.
This hill has already been several times mentioned, especially with
reference to the remarkable manner in which the white calcareous stratum,
in other parts so horizontal (Figure 2), dips under it into the sea. It has
a broad summit, with obscure traces of a crateriform structure, and is
composed of basaltic rocks (Of these, one common variety is remarkable for
being full of small fragments of a dark jasper-red earthy mineral, which,
when examined carefully, shows an indistinct cleavage; the little fragments
are elongated in form, are soft, are magnetic before and after being
heated, and fuse with difficulty into a dull enamel. This mineral is
evidently closely related to the oxides of iron, but I cannot ascertain
what it exactly is. The rock containing this mineral is crenulated with
small angular cavities, which are lined and filled with yellowish crystals
of carbonate of lime.), some compact, others highly cellular with inclined
beds of loose scoriae, of which some are associated with earthy lime. Like
Red Hill, it has been the source of eruptions, subsequently to the
elevation of the surrounding basaltic plain; but unlike that hill, it has
undergone considerable denudation, and has been the seat of volcanic action
at a remote period, when beneath the sea. I judge of this latter
circumstance from finding on its inland flank the last remains of three
small points of eruption. These points are composed of glossy scoriae,
cemented by crystalline calcareous spar, exactly like the great submarine
calcareous deposit, where the heated lava has rolled over it: their
demolished state can, I think, be explained only by the denuding action of
the waves of the sea. I was guided to the first orifice by observing a
sheet of lava, about two hundred yards square, with steepish sides,
superimposed on the basaltic plain with no adjoining hillock, whence it
could have been erupted; and the only trace of a crater which I was able to
discover, consisted of some inclined beds of scoriae at one of its corners.
At the distance of fifty yards from a second level-topped patch of lava,
but of much smaller size, I found an irregular circular group of masses of
cemented, scoriaceous breccia, about six feet in height, which doubtless
had once formed the point of eruption. The third orifice is now marked only
by an irregular circle of cemented scoriae, about four yards in diameter,
and rising in its highest point scarcely three feet above the level of the
plain, the surface of which, close all round, exhibits its usual
appearance: here we have a horizontal basal section of a volcanic spiracle,
which, together with all its ejected matter, has been almost totally
obliterated.
The stream of lava, which fills the narrow gorge eastward of the town of
Praya, judging from its course, seems, as before remarked, to have come
from Signal Post Hill, and to have flowed over the plain, after its
elevation (The sides of this gorge, where the upper basaltic stratum is
intersected, are almost perpendicular. The lava, which has since filled it
up, is attached to these sides, almost as firmly as a dike is to its walls.
In most cases, where a stream of lava has flowed down a valley, it is
bounded on each side by loose scoriaceous masses.): the same observation
applies to a stream (possibly part of the same one) capping the sea cliffs,
a little eastward of the gorge. When I endeavoured to follow these streams
over the stony level plain, which is almost destitute of soil and
vegetation, I was much surprised to find, that although composed of hard
basaltic matter, and not having been exposed to marine denudation, all
distant traces of them soon became utterly lost. But I have since observed
at the Galapagos Archipelago, that it is often impossible to follow even
great deluges of quite recent lava across older streams, except by the size
of the bushes growing on them, or by the comparative states of glossiness
of their surfaces,--characters which a short lapse of time would be
sufficient quite to obscure. I may remark, that in a level country, with a
dry climate, and with the wind blowing always in one direction (as at the
Cape de Verde Archipelago), the effects of atmospheric degradation are
probably much greater than would at first be expected; for soil in this
case accumulates only in a few protected hollows, and being blown in one
direction, it is always travelling towards the sea in the form of the
finest dust, leaving the surface of the rocks bare, and exposed to the full
effects of renewed meteoric action.
INLAND HILLS OF MORE ANCIENT VOLCANIC ROCKS.
These hills are laid down by eye, and marked as A, B, C, etc., in Map 1.
They are related in mineralogical composition, and are probably directly
continuous with the lowest rocks exposed on the coast. These hills, viewed
from a distance, appear as if they had once formed part of an irregular
tableland, and from their corresponding structure and composition this
probably has been the case. They have flat, slightly inclined summits, and
are, on an average, about six hundred feet in height; they present their
steepest slope towards the interior of the island, from which point they
radiate outwards, and are separated from each other by broad and deep
valleys, through which the great streams of lava, forming the coast-plains,
have descended. Their inner and steeper escarpments are ranged in an
irregular curve, which rudely follows the line of the shore, two or three
miles inland from it. I ascended a few of these hills, and from others,
which I was able to examine with a telescope, I obtained specimens, through
the kindness of Mr. Kent, the assistant-surgeon of the "Beagle"; although
by these means I am acquainted with only a part of the range, five or six
miles in length, yet I scarcely hesitate, from their uniform structure, to
affirm that they are parts of one great formation, stretching round much of
the circumference of the island.
The upper and lower strata of these hills differ greatly in composition.
The upper are basaltic, generally compact, but sometimes scoriaceous and
amygdaloidal, with associated masses of wacke: where the basalt is compact,
it is either fine-grained or very coarsely crystallised; in the latter case
it passes into an augitic rock, containing much olivine; the olivine is
either colourless, or of the usual yellow and dull reddish shades. On some
of the hills, beds of calcareous matter, both in an earthy and in a
crystalline form, including fragments of glossy scoriae, are associated
with the basaltic strata. These strata differ from the streams of basaltic
lava forming the coast-plains, only in being more compact, and in the
crystals of augite, and in the grains of olivine being of much greater
size;--characters which, together with the appearance of the associated
calcareous beds, induce me to believe that they are of submarine formation.
Some considerable masses of wacke, which are associated with these basaltic
strata, and which likewise occur in the basal series on the coast,
especially at Quail Island, are curious. They consist of a pale yellowish-
green argillaceous substance, of a crumbling texture when dry, but unctuous
when moist: in its purest form, it is of a beautiful green tint, with
translucent edges, and occasionally with obscure traces of an original
cleavage. Under the blowpipe it fuses very readily into a dark grey, and
sometimes even black bead, which is slightly magnetic. From these
characters, I naturally thought that it was one of the pale species,
decomposed, of the genus augite;--a conclusion supported by the unaltered
rock being full of large separate crystals of black augite, and of balls
and irregular streaks of dark grey augitic rock. As the basalt ordinarily
consists of augite, and of olivine often tarnished and of a dull red
colour, I was led to examine the stages of decomposition of this latter
mineral, and I found, to my surprise, that I could trace a nearly perfect
gradation from unaltered olivine to the green wacke. Part of the same grain
under the blowpipe would in some instances behave like olivine, its colour
being only slightly changed, and part would give a black magnetic bead.
Hence I can have no doubt that the greenish wacke originally existed as
olivine; but great chemical changes must have been effected during the act
of decomposition thus to have altered a very hard, transparent, infusible
mineral, into a soft, unctuous, easily melted, argillaceous substance.
(D'Aubuisson "Traite de Geognosie" tome 2 page 569 mentions, on the
authority of M. Marcel de Serres, masses of green earth near Montpellier,
which are supposed to be due to the decomposition of olivine. I do not,
however, find, that the action of this mineral under the blowpipe being
entirely altered, as it becomes decomposed, has been noticed; and the
knowledge of this fact is important, as at first it appears highly
improbable that a hard, transparent, refractory mineral should be changed
into a soft, easily fused clay, like this of St. Jago. I shall hereafter
describe a green substance, forming threads within the cells of some
vesicular basaltic rocks in Van Diemen's Land, which behave under the
blowpipe like the green wacke of St. Jago; but its occurrence in
cylindrical threads, shows it cannot have resulted from the decomposition
of olivine, a mineral always existing in the form of grains or crystals.)
The basal strata of these hills, as well as some neighbouring, separate,
bare, rounded hillocks, consist of compact, fine-grained, non-crystalline
(or so slightly as scarcely to be perceptible), ferruginous, feldspathic
rocks, and generally in a state of semi-decomposition. Their fracture is
exceedingly irregular, and splintery; yet small fragments are often very
tough. They contain much ferruginous matter, either in the form of minute
grains with a metallic lustre, or of brown hair-like threads: the rock in
this latter case assuming a pseudo-brecciated structure. These rocks
sometimes contain mica and veins of agate. Their rusty brown or yellowish
colour is partly due to the oxides of iron, but chiefly to innumerable,
microscopically minute, black specks, which, when a fragment is heated, are
easily fused, and evidently are either hornblende or augite. These rocks,
therefore, although at first appearing like baked clay or some altered
sedimentary deposit, contain all the essential ingredients of trachyte;
from which they differ only in not being harsh, and in not containing
crystals of glassy feldspar. As is so often the case with trachytic
formation, no stratification is here apparent. A person would not readily
believe that these rocks could have flowed as lava; yet at St. Helena there
are well-characterised streams (as will be described in an ensuing chapter)
of nearly similar composition. Amidst the hillocks composed of these rocks,
I found in three places, smooth conical hills of phonolite, abounding with
fine crystals of glassy feldspar, and with needles of hornblende. These
cones of phonolite, I believe, bear the same relation to the surrounding
feldspathic strata which some masses of coarsely crystallised augitic rock,
in another part of the island, bear to the surrounding basalt, namely, that
both have been injected. The rocks of a feldspathic nature being anterior
in origin to the basaltic strata, which cap them, as well as to the
basaltic streams of the coast-plains, accords with the usual order of
succession of these two grand divisions of the volcanic series.
The strata of most of these hills in the upper part, where alone the planes
of division are distinguishable, are inclined at a small angle from the
interior of the island towards the sea-coast. The inclination is not the
same in each hill; in that marked A it is less than in B, D, or E; in C the
strata are scarcely deflected from a horizontal plane, and in F (as far as
I could judge without ascending it) they are slightly inclined in a reverse
direction, that is, inwards and towards the centre of the island.
Notwithstanding these differences of inclination, their correspondence in
external form, and in the composition both of their upper and lower parts,-
-their relative position in one curved line, with their steepest sides
turned inwards,--all seem to show that they originally formed parts of one
platform; which platform, as before remarked, probably extended round a
considerable portion of the circumference of the island. The upper strata
certainly flowed as lava, and probably beneath the sea, as perhaps did the
lower feldspathic masses: how then come these strata to hold their present
position, and whence were they erupted?
In the centre of the island there are lofty mountains, but they are
separated from the steep inland flanks of these hills by a wide space of
lower country: the interior mountains, moreover, seem to have been the
source of those great streams of basaltic lava which, contracting as they
pass between the bases of the hills in question, expand into the coast-
plains. (I saw very little of the inland parts of the island. Near the
village of St. Domingo, there are magnificent cliffs of rather coarsely
crystallised basaltic lava. Following the little stream in this valley,
about a mile above the village, the base of the great cliff was formed of a
compact fine-grained basalt, conformably covered by a bed of pebbles. Near
Fuentes, I met with pap-formed hills of the compact feldspathic series of
rocks.) Round the shores of St. Helena there is a rudely formed ring of
basaltic rocks, and at Mauritius there are remnants of another such a ring
round part, if not round the whole, of the island; here again the same
question immediately occurs, how came these masses to hold their present
position, and whence were they erupted? The same answer, whatever it may
be, probably applies in these three cases; and in a future chapter we shall
recur to this subject.
VALLEYS NEAR THE COAST.
These are broad, very flat, and generally bounded by low cliff-formed
sides. Portions of the basaltic plain are sometimes nearly or quite
isolated by them; of which fact, the space on which the town of Praya
stands offers an instance. The great valley west of the town has its bottom
filled up to a depth of more than twenty feet by well-rounded pebbles,
which in some parts are firmly cemented together by white calcareous
matter. There can be no doubt, from the form of these valleys, that they
were scooped out by the waves of the sea, during that equable elevation of
the land, of which the horizontal calcareous deposit, with its existing
species of marine remains, gives evidence. Considering how well shells have
been preserved in this stratum, it is singular that I could not find even a
single small fragment of shell in the conglomerate at the bottom of the
valleys. The bed of pebbles in the valley west of the town is intersected
by a second valley joining it as a tributary, but even this valley appears
much too wide and flat-bottomed to have been formed by the small quantity
of water, which falls only during one short wet season; for at other times
of the year these valleys are absolutely dry.
RECENT CONGLOMERATE.
On the shores of Quail Island, I found fragments of brick, bolts of iron,
pebbles, and large fragments of basalt, united by a scanty base of impure
calcareous matter into a firm conglomerate. To show how exceedingly firm
this recent conglomerate is, I may mention, that I endeavoured with a heavy
geological hammer to knock out a thick bolt of iron, which was embedded a
little above low-water mark, but was quite unable to succeed.
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