f-

9^,4:

d

/^^/

I Sketch of the Geological
idian Island of St. Croix, or

■l.G.S. The Author, Christiansted,

work under consideration begins as

3f the geological formations of our island, to
backwards, it may be instructive, in sunimar-
: course, and, as far as possible, note leading

^'~* / / / ible suggestion that tlie components

' **-*'^ / *^» '^ lat rock was formed, we, and prob-

alline structure prevalent in our older forma-
which they are composed were deposited, and
tting them through have been intruded so that
sly to their deposition.

old enough to suppose this fact without first
choolmaster, or, as modern American termi-
ittempts in twelve dismal chapters and with
her with a map as recent as 1856, to "edu-
• building or formation of the island of St.
The above quotation gives an idea of his
npt to give specimens of the pedantry dis-
lok. It is dilficult to conceive whether that
public or for a primary school. If for the
in the first chapter, the tiresome and almost
y lime-rock effervesces in muriatic acid and
nt that soils are classed among rocks, and
raminiferae and the like are wholly super-
he text has too many pretensions to being

conclusions. All we can discern is, that the

may have been two successive formations of

he Cretaceous period and followed by sub-

and subsequent deposits so as to form an-

at the time of the chalk formation. Trap

[ y I J ji y ' bave, to a limited extent, risen to the de

W «^/ /PU^ y^i^-L,.^-, /h^C*^ t.,^,*-^*^^ j„ „^j 3,j^^pj ,^ penetrate any further

ing the reader much patience in his endea-
ire mostly quite commendable. A. F. B.

1

\. t-./N

«

6/^

t

tS" ii^w ^li**f L^ff^ Ix^v^^Xa, jd^^^*^

^.

tA"^'.

4,^

x^:?c«. 'p,i^ .

I Sketch of the Geological
idian Island of St. Croix, or

S.G.S. The Author, Christiansted,

work under consideration begins as

Df the geological formations of our island, to
backwards, it may be instructive, in summar-
: course, and, as far as possible, note leading

alline structure prevalent in our older forma-
which they are composed were deposited, and
tting them through have been intruded so that
jly to their deposition.

able suggestion that the components
lat rock was formed, we, and prob-

old enough to suppose this fact without first
choolmaster, or, as modern American termi-
ittempts in twelve dismal chapters and with
her with a map as recent as 1856, to "edu-
; building or formation of the island of St.
The above quotation gives an idea of his
npt to give specimens of the pedantry dis-
ook. It is difficult to conceive whether that
public or for a primary school. If for the
in the first chapter, the tiresome and almost
y lime-rock effervesces in muriatic acid and
,'nt that soils are classed among rocks, and
)raminifera; and the like are wholly super-
the text has too many pretensions to being

conclusions. All we can discern is, that the
may have been two successive formations of
the Cretaceous period and followed by sub-
and subsequent deposits so as to form an-
is" at the time of the chalk formation. Trap
s have, to a limited extent, risen to the de-
'e do not attempt to penetrate any further
ing the reader much patience in his endea-
are mostly quite commendable. A. F. B.

^}l(j^ . V«AAe.)(5 V , FX'Jr^ » '>'\ * t

C-Jl* ^ ff\

m

..rV

r,>«v,.»4t^^

»i

^ '^

-»<t

v^

The Building of an Island, being a Sketch of the Geological

Structure of the Danish West Indian Island of St. Croix, or

Santa Cruz. By John T. Quin. F.R.G.S. The Author, Christiansted,

St. Croix. igo7. 4to.

The twelfth or concluding chapter of the work under consideration begins as

follows:

While it seems desirable, in entering on the study of the geological formations of our island, to
betcin with the younger set of rocks and trace the story backwards, it may be instructive, in suramar-
izin:; the results of our observations, to take the opposite course, and, as far as possible, note leading
even Is and conditions in their natural sequence.

As a preliminary, we must remember that the crystalline structure prevalent in our older forma-
tion has I, -n induced in the strata since the materials of which they are composed were deposited, and
similarly that the dikes of igneous rock which we find cutting them through have been intruded so that
in the first instance we have to confine our thoughts simply to their deposition.

While th.iiil<ing the author for the valuable suggestion that the components
of a rock were on hand when and where that rock was formed, we, and prob-
ably a great many others, had been bold enough to suppose this fact without first
consulting him. He is manifestly a schoolmaster, or, as modern American termi-
nology has it, an "educator," and he attempts in twelve dismal chapters and with
the aid of diagrams and plans, together with a map as recent as 1856, to "edu-
cate" us to a vague conception of the building or formation of the island of St.
Croix in the Danish West Indies. The above quotation gives an idea of his
average style, but we shall not attempt to give specimens of the pedantry dis-
played in almost every part of the book. It is diificult to conceive whether that
book is written for a well-informed public or for a primary school. If for the
former, the childish object lessons, as in the first chapter, the tiresome and almost
offensive explanation of the cause why lime-rock effervesces in muriatic acid and
clay does not, the interesting statement that soils are classed among rocks, and
the almost endless dissertation on Foraminiferae and the like are wholly super-
fluous; if for children, the bulk of the text has too many pretensions to being
technical.

We look in vain for terse, logical conclusions. All we can discern is, that the
author favours the opinion that there may have been two successive formations of
the island, one, possibly anterior of the Cretaceous period and followed by sub-
mersion; then again, slow upheavals and subsequent deposits so as to form an-
other dry surface. The latter "perhaps" at the time of the chalk formation. Trap
dikes indicate that the volcanic forces have, to a limited extent, risen to the de-
gree of eruption on the surface. We do not attempt to penetrate any further
into the intricacies of the book, wishing the reader much patience in his endea-
vours to peruse it. The illustrations are mostly quite commendable. A. F. B.

i

^0^

/h^htio.^ l/cU^oU-

THE BUILDING OF AN ISLAND,

BEING A SKETCH

OF THE GEOLOGICAL STRUCTURE OF THE

DANISH WEST INDIAN ISLAND OF

ST. CROIX, OR SANTA CRUZ.

BY

JOHN T. QUIN, F.R.G.S.

Royal Medalist, Denmark ; lately Inspector of Schools in the Danish West Indies.

LIHRART
NEW YORK
BOTANICAL

OARDEN

1907

Printed in New York by Chauncey Holt,

and Published by the Author in Christiansted. St. Croix.

PREFACE.

The following pages contain the results of the writer's study of the geological struc-
ture of St. Croix from time to time through a long period of residence in the island. Had ■
these results been stated for the information of the professional or amateur geologist they
could have been described in much fewer words than are here given to them — the map with
two or three pages of notes would have been suflBcient ; but they have been here recorded
with quite another purpose. It has been the aim of the writer to open up for the reader,
whether resident or visitor, to whom the subject is new, or only slightly known, a field of
great and varied interest.

There are doubtless many people who find it easy to understand that the vegetation
of an island, its trees, shrubs and herbs with their flowers, may constitute a very attractive
subject, and that the same may be true of its insects or its shells ; but it has, perhaps, never
even occurred to them that the study of the solid structure of the island can possess any
wreat attraction. They have never asked themselves such questions as : What is beneath
our feet ? What is it made of ? How came it there ? Is it a solid mass merely, or does it
show arrangement of parts, and if so, of what parts, and how are those arranged ? It is
hoped by the writer that some at least of those who read the.se pages may come to see that
such questions as these can be answered, and that the observations which we make in order
to answer them lead to others, also of a very attractive character.

It has been truly said that a great part of an educator's success depends on his ability
to rouse the spirit of inquiry in his pupils. They will then work for themselves, and the
knowledge they acquire in this way is not likely to be forgotten. It takes little reflection
to see that it is the spirit of inquiry in mankind to which we owe all those great discoveries
and inventions that have placed the present generation in the advanced position which it
occupies in regard to the use it is able to make of the various powers of Nature. A frag-
ment of amber rubbed on a piece of cloth attracts light straws, etc. Why ? The continued
pressure of this " Why" at every step of the inquiry has led to all the marvels of electrical
science as we now have it, and who can tell how far it may yet lead us ? Watt looks at the
rising lid of the steaming kettle, asks Why ? and we get a revolution in the building of
steam-engines. Torricelli sees that a suction pump will not lift water higher than about
thirty feet : he asks Why ? and we get the barometer. And so with every great discovery
and invention' that has been given to the world, it is the result of the activity of the inquir-
ing mind of man. For the mass of us there will, of course, be no results of our inquiries
which can affect the comfort and happiness of any large portion of our fellow men, but they
can very greatly affect our own personal comfort and happiness. The habit of inquir5^
leads to that pleasant occupation of the mind which tends to raise its tone, which continually

*^ gives matter for study and reflection, renders ennui impossible, and makes such questions

'"" as, Is life worth living ? absurd.

j^ Such reflections as these suggest that it might be well to try to niduce the advanced

Cj pupils in our schools to ob,serve for themselves the common things around them, and to

vi Preface.

make the inquiries which will naturally follow. Why is one pebble smooth and round
while a second is smooth but angular and a third is both angular and rough ? Why is a
fourth marked with streaks, a fifth with spots, and so on ? Such questions would no doubt
in the first instance have to be answered by the teacher, but they should alwaj-s be answered
when possible by referring the pupil to a spot where he will see the answer demonstrated.
By-and-by he will learn to find answers for himself.

This leads to the remark that the reader of these pages should in no case be satisfied
with merely reading the descriptions and conclusions of the writer, but should as far as pos-
sible visit the places named and see for himself. He should go armed with a lens and a
pocket compass, and verify the writer's observations, or correct them, as the case may be.
In this way he will find new points continually cropping up, and the range of his inquiry
continually increasing. By-and-by he will find that in the .study of even this little island
he has gained some insight into the ways in which mountains have been formed and lifted,
the way plains have been levelled and valleys carved out, not only here and in other islands,
but also in those greater lands which occupy a large part of the surface of our globe. As
an introduction to an intelligent study of physical geography, the local study will thus be-
come invaluable, and if these pages should lead the reader to undertake such local study,
they will have served the purpose for which they are intended.

NOTES ON THE MAP.

The map is reduced to half size, linear measurement, from the chart of Santa Cruz, drawn after a
survey by Mr. John Parsons in 1856, and published at the Hydrographic Office of the British Admiralty,'
London.

It is hoped that the present map will be found fairly accurate ; but the reader who wishes to follow
up the observations noted in the following pages should procure a copy of the above-mentioned chart or of
one published at the Hydrographic Office, Washington, on which to note such faflts as he may learn about
the character and slope of the strata, etc.

The full names of the estates and other points indicated by initials on the map are printed in col-
umns corresponding with the section in which the places are respectively found. They are also arranged,
as far as possible, in a descending order answering to the positions of the places.

The reader is advised not to take any notice of the red and blue lines which cross the map until he
has read the account of them given in the text. They are mostly ruled lines, but it must not be supposed
that the bends in the strata indicated by them are equally straight, and it may be that further detailed ex-
amination of the rocks may make some modifications necessary.

H B— Ham's Bay.

N S— North Side.
B B— Butler's Bay,
S H— Sprat Hall.

H Bl— Ham's Bluff.

S G— Spring Garden.

A- Annaly.

M S— Mt. Stewart.

P— Punch. O— Oxford.

O G— Orang;e Grove.

M— Montpellier.

T F— Two Friends.

J H— Jollv Hill.

B G— Beck's Grove.

A— Allandale.

H— Hope.

N S— North Star.

C B — Cane Bay.

La V— La Valine.

P — Prosperity.

C — Canaan.

M E— Mt. Eagle.

B M — Blue Mountain.

F — Fountain.

M P C— Mt. Pleasant

(Colquohoun).
R— River.
U L — Upper Love.
G P — Grove Place.
L L— Lower Love.

R T— Rust op Twist.

B B— Baron's Bluff.

S R— Salt River.

L H— Lebanon Hill.

W— Windsor.

U C — Upper Concordia.

M S — Morning Star.

M— Montpellier.

G— Glynn.

R— Rattan.

M B— Mon Bijou.

M — Moravian Station.

(Friedensfeld).
B E — Bonne P>sperance.
S H— Sion Hill.
M F— Mary's Fancy.

S R P— Salt River Point.

J F— Judith's Fancy.

S J— St. John's,

L P — La Princesse.

Lt P— Little Princess.

L R^Long Reef.

O G — Orange Grove,

A H— Alder's Hvile.

S H— Sion Hill.

C H— Constitution Hill,

B M— Bulow's Minde.

H H— Hermon Hill,

Fr— Prederiksted.
S P— Sandy Point.

S G H— St. George's Hill.

L C — Lower Concordia.

W— Whim.

C — Carlton.

Cn -Cane.

H R— Hannah's Rest.

C — Camporico.

G H— Good Hope.

W B— White's Bay.

L P— Long Point.

M — Mountain.

D S— Diamond School.

M— Mt. Pleasant.

A — Adventure.

G G— Golden Grove

Residence.
P— Paradise.
N B— Negro Bay.
W D— William's Delight
M B — Manning's Bay.
E— Enfield.
B H — Betty'i Hope.

L R — La Reine.

S— Slob.

S H— Strawberry Hill.

D — Diamond and Ruby

K H— King's Hill.

O M— Old Mill.

B S— Barren Spot.

S T— Spanish 'Town.

B— Blessing.

H— Hope.

J— Jerusalem.

A— Anguilla.

K L — krause Lagoon.

K P— Krause Point.

L R— Long Reef.

C C— Castle Coakley,

P R— Peter's Rest.

A H — Anna's Hope.

G E— Grange.

C R— Catherine's Rest.

W R— Work and Rest.

J — Jerusalem.

C G— Cane Garden.

G — Granard.

D K— Diamond Keturah.

W P— Waiter's Point.

A — Fort Augusta,
h — Christiansted.
h L — Christiansted

Lagoon.
—The Kay.
— Shoys.
— Bostzburg.
H— Lowry Hill,
P— St. Peter's.

G K— Green Kay

Islet and Estate,
P P— Pull Point.
S G— South Gate.
E H— Easthill School.
C B— Coakley Bay.
S— Solitude.

— Munster.
—Springs.
— Fareham.
—Longford.

M W— Mt Washington
Estate.
P— Petronella.
G P— Great Pond.
C G— Cotton Grove.

M C— Madam Carty.
T H— Turner's Hole.
G T B— Grape Tree Bay

CONTENTS.

PAGE

Chapter I i

Introductory. Position and size of the island. The submarine Santa Cruz.
Outline of the island. Surface— Western Oblong, Eastern Triangle, Intervening
Neck. The two rock-formations of the island.

Chapter II 9

The Limestone and Marl Formation in the Central Slope. Lenses. Foraminif-
erous shells. Contributors to the sea-sand of the submarine Santa Cruz. Con-
tributors to the Limestone Formation. Thinning out. Conclu.sions from
foregoing observations. Slope of the beds, outcrop, strike, dip, clinometer.
Use of the compass. How to find the synclinal axis.

Chapter III 24

The Limestone and Marl Formation outside of the Central Slope. The anti-
clinal axis of the Mt. Eagle Ridge. The Kingshill Range. The four smaller
hills. The limestone formation in the plains. The West End strata. Irregulari-
ties, faults. Thickness of the Limestones and Marls. Beach and reef limestones.

Chapter IV 34

The Blue-beach or indurated-clay formation. Nature and origin of the strata.
Their crystalline character. High dips. Relative positions of the two forma-
tions. The limestones and marls resting uncomformably on the blue-beach
strata. Deposition of the strata in the sea. Limestone beds of the blue-beach
formation. Waiter's Point and its fossils. Conglomerates. Travertine. The
variolitic structure. Jointing. Cleavage in the slate beds.

Chapter V 44

Arrangement of the blue-beach rocks. Dips classified. Arrangement of the
rocks in the Western Oblong. The anticlinal of the Northwest and its axis.
Synclinal axis of the Northwest. Strata of the Eastern Triangle , their anti-
' clinals and synclinals. Contortions. Summary.

Chapter VI 53

The Igneous Rocks. Dykes and masses of trap rock.

Chapter VII 57

Minerals.

Chapter VIII 61

The Sculpturing of the island. Action of the sea on cliffs and bays. Rains and
streams. Preparatory action of the atmoiphere. Formation of valleys. Effect
of hardness in the strata. How heavy blocks move down the hillsides. Forma-
tion of plains. Immensity of geological periods.

Chapter IX 7°

Connection of the foregoing with the physical geography of the island. Origin
of the hill ranges. The valley through the Christiansted Hills. Probable
arching of the strata of the Central Slope towards northeast. The Central and
Southwestern Plains. The Lagoons. The forms of the Valleys.

viii Contents.

Chapter X 75

Relation of the Structure of St. Croix to that of the other West Indian Islands.
The two great axes of the West Indies. St. Thomas, Vieques, St. John, Tortola,
Virgin Gorda, Anegada, Bahamas. Non- volcanic islands to the south, including
Barbados.

Chapter XI 82

The Relation of the geology of St. Croix to geology in general. In regard to
modes of origin of the rocks, their times of origin or relative ages, and their
subsequent history. JValue of fossils in determining the ages of the strata.
Geological systems. Age of the West Indian Volcanic Chain.

Chapter XII 99

Conclusion, Summary of events and successive conditions in their natural
sequence.

Notes 103

On finding the anticlinal axis of the Northwest.

Notes 105

On finding the anticlinal and synclinal axes of the Eastern Triangle.

CHAPTER I.
INTRODUCTORY.

The Island, ns Posri'ioN and Si/k.

The Danish West Indian island of St. Croix, or Santa Cruz, lies in the
northeast corner of the Caribbean Sea. 1 1 has an elonifjated form, stretching
Ironi east-northeast to west-southwest and measures a Irille over 22 English
miles in length, while its greatest breadth is only about si.x miles. Its area is
abcjut 80 English sq. miles, say three fourths the size of the Isle of Wight or
a little over one third of the size of Bornholm.

It is the largest of the three Danish West Indian Islands, St. Thomas
containing about 23 English s(|. miles and St. .lohn 20- miles. Cumparing it
with a few of the smaller liritish islands in these seas we find that it is about
half the size (jf Barbadoes, three fourths the size of Antigua and a little over
the size of St. Kitts.

TiiK SriiMARiNE Santa Ckiz.

When we examine a chart of the island shewing the soundings around its
shores, we lind that while it rises rather abrLiptIv from the sea on the north-
west and west, it is bordered on all other sides by an extensive bank, nn which
the depth of water only at a few points along the edges exceeds 20 fathoms,
and is commonly very much less, and from which the descent into the deep sea
is steep, though not so steep as in the northwest. This bank, which on the
map is enclosed by the 100 fathom line, and is at least as extensive as the island
itself, may be looked upon as a sort of submarine Santa Cruz, and the study
(){ it, as we shall see later, throws a Hood of light on the story of the building
up of the island.

I'-QRM 01^ TIIK IS[-.'\ND.

TiiE Westeun' Oblong.

The .Xeck.

TiiE ICastern Trungle.

2 the buildixg of an island.

The Isi,and's Outijxe.

When \vc now examine the form of the island itself, we see at once that
it may be regarded as consisting of three parts, namely, an oblong portion to the
west, a narrow triangle to tiie east, and in the middle a neck bv which the
two other parts are united.

This peculiarity of outline should be carcfuUv noted, for we shall shortly
find that, simple and obvious as it is, it has a most intimate connection with
the storv to be studied. We mav observe in passing that the town of Chris-
tiansted stands on the northern shore of the island at the narrowest part of the
neck just mentioned, while the town of Frederiksted stands on the western
shore.

The Island's Surface. — The " Western Oiu.ong."

From this general view of the outline of the island we mav proceed to
consider its surface. Referring to the map, and confining our attention in the
first place to the vjcstcrn oblong, we notice that the northern part of this oblong
is covered with hills, while its southern part, stretching to the sea, is a plain,
broken in its eastern part onlv bv a few low hills. Leaving for the present
this plain, which also extends itself through the eastern part of the oblong and
as a narrow valley reaches the northern shore, we may give our attention to the
northern hills. The whole chain of these northern hills is naturally divided
into three parts. The first of these to be noticed is a short ridge lying north-
west and southeast and containing the chief elevations of the island, namely,
Bbie Mountain (1090 ft.) at its southern end and Mount Eagle (1 164 ft.) at its
northern end. This ridge is the most conspicuous feature of the island.
From the wharf at St. Thomas (40 miles away to the north), it is almost the
only part of Santa Cruz that is visible. Viewed from the central part of
Santa Cruz itself it is also a conspicuous object. That this ridge is an important
feature of the island's geography may be further inferred from the fact that
the di'ainaafe of the valley on its eastern side is turned to the northeast and
finally flows out, by the creek known as Salt River, on \\\q nor t ha- n shore oiX.\\Q
island, while the drainage of the valley on the western side is turned southwards
and flows out on the soutJiemi shore.

The above ridge is connected bv lower hills witli a range to the eastward
known as the Salt River Hills, the highest point of which (towards its east end)
is 872 ft. above the sea-level. The spurs of this range press on the sea shore^
along which a picturesque road is carried to reach the vallev which in part
marks off the range from the Mt. Eagle Ridge, or, more accurately speaking,
from a spur of that ridge.

On the west side of the Mt. Eagle Ridge low hills connect it with an
extensive group, which must be regarded rather as a block of hills than a range.
This block of hills fills up the northwestern corner of the island, and has on
its eastern edge some elevations of over goo ft., while towards the west are
Mt. Washington, 807 ft., and a liill east of Frederiksted, 850 ft.

THE BUILDING OF AN ISLAND.

4 THE BUILDING OF AN ISLAND.

The hills of the nortli side of the island (or, on the north side of the
western oblong), though all connected by lower elevations, may then be regarded
as consisting of three parts : i — The Mount Eagle Ridge, 2 — The Salt River
Hills to the east of that ridge, and. 3 — The much more important northwestern
block of hills lo the west of it.

Thk Eastern Triangle.

If we now leave the western oblong and cross over the intervenins' neck to
the eastern triangle (known as the East End), we find the central strip of that
triangle to be occupied by a range of hills, not so high as those of the north-
west, hut still reaching in several places a height of over 800 ft. The range is
continuous, yet, like the hills of the northern chain, it is naturally divided into
three parts. This division is plain enough when the range is seen from the sea,
and becomes very striking when it is viewed from the top of Blue Mountain,
from which elevated point it does not look like a continuous range at all, but
appears to be three clumps of hills, one behind the other.

The three groups into which the eastern range of hills is seen to be divided,
are, first the Christiansted Hills, nexi the Mt. Washington Hills, and lastly, the
small Goat Hills group at the eastern extremity of the island.

The Christiansted group is slit across from north to south by a narrow
valle}', which forms a locally well-known landmark for sailors and is called
among them " The Saddle." This valley, which in its highest point rises to
about 400 feet, has on its western side a peak of 855 ft. in height (Signal Hill,
looking down on the town), and on its eastern side several peaks of between
seven and eight hundred feet. The height of the group decreases eastwards,
and it is joined to the ne.xt group by low hills of about 300 feet, while it is well
marked off from that group by the small plains of " Southgate " on the north
side and " Great Pond " on the south, each having a large pond near the shore.

The Mt. Washington group has a peak of 860 ft. with others not much
less, and sinks gradually to 400 ft. at its eastern end, where it is divided by a
valley crossing a narrow neck of the island at " Grape Tree Bay " from the
small " Goat Hills " group, the highest point of which reaches 660 feet.

Having now seen that there are two principal hill ranges on the island,
namely, those of the ivestern oblong and those of the eastern triangle, we may
next look at them in their relation to each other. After noticing, as we have
already done, that they are parted from each other by what we have called an
intervening 7ieck, we notice that they are not in the same straight line; yet in
their general direction are parallel to each other, so that, if continued, they
would run side by side, with their crests about three and a half English miles
apart. The eastern range ends rather abruptly at Christiansted. The northern
range stops in like manner at Salt River, but is represented farther east by a
few low hills along the northwest shore of the " neck " and by the islet called
'' BuCfk Island" (summit 340 ft. above sea-level), and the submarine bank from
which that islet rises.

THE r.UILDlNG OF AN ISLAND.

THK I'.riLltINC OF AN 1SI,ANI).

The Intervkninc. Neck.

Wc mav now leave for the present the two divisions of the Island which
have been described as the -n'cstcrn oblong and the eastern triangle and turn our
attention to the intervening neek. We see from the map that this neck is
narrowest near Christiansted, where it joins the eastern triangle. It is there not
more than three miles wide, but it broadens westwards, for the coast from
Christiansted does not follow the general trend of the northern shore, but runs
northwest to Salt River Point, a distance of about four English miles. Along
this strip of shore lies a beautiful little jilain which, from the names of the
sugar estates which occupy it, may be called the ''Princess'' plain. At the
back of this plain and Iving parallel with the shore is a range of hills having as
its highest points heights of between 500 and 600 feet. Tliis little range forms
the northern edge of an undulating tract of country which slopes gradually
down from it towards the island's southern shore. This sloping tract, which
mav appropriately be called the Central Slope, is separated by valleys on either
hand from the higher hill ranges to the east and to the northwest of it. The
sketch shows how the hills forming its northeastern edge and looking over the
Princess plain, look in outline as seen from the sea. This is the only
part of the island where the sugar cultivation comes over, at the present
day, to the north shore. It is thus the most beautiful part of the north
coast, and for us in regard to our present purpose it has very great interest,
for it is with this Central Slope that we shall presently begin our study
of the island's structure. Turning for a moment to this slope as depicted
on the map, we see that on its eastern side it is scored bv vallevs that run
to the southwest while on its western side the valleys which furrow it
run to the south. The plain which separates it from the eastern range of hills
is onlv a small one; but that which divides it from the northern hills widens
rapidly southwards and opens into the wide plain south of those hills, forming
with it the richest part of the island. A few low hills along the south shore
are, as we shall see later, of the same general structural character as the central
hillv slope, but are separated from it bv a valley reaching the southern shore,
namely, past the estates La Reine, Barren Spot and Hope.

Fic. 6.

the building of an island. 7

The Rocks ok the Island.

The above sketch of the geograph\' of the island may perhaps be sufficient
as an introduction to our study of its structure; further details may be noticed
as we proceed.

The surface described is clothed nearly everywhere with vegetation, which
to a great extent hides the soil. In the cultivated parts of the island, how ever,
we may often see large areas of the soil exposed, antl in the uncultivated
portions the sides of the watercourses and the cuts made by the small rills
running down the hillsides also afford us peeps at the soil and the subsoil.
When now we take advantage of these various opportunities, and examine the
soils in different parts of the island we soon see that they differ very considerably
from eacii other, and if we examine the stones found in them we find that they
also vary a good deal. Sometimes, moreover, we get to see, in road-cuttings
and elsewhere, what lies beloiv the soil, that is to say we get to see some of the
substances which make up the solid mass of our island, and we soon perceive
that thev too show noticeable differences. In some cases they differ only slightly
from each other and we mav put them in the same class; but in other cases
thev differ so much that we have to put them in separate classes. If we take
our specimens from any quarry or " gravel pit " in the East End or from the
hills of the north and west we shall find that they generalh' bear a great re-
semblance to each other; they most frequently have a rusty look, especially
those that have been long exposed to the weather. These sometimes crumble
to pieces and are then often spoken of as "rotten rock"; but if we go deeper
into the rock in the quarry and break a piece through, we find that it is hard
and crystalline and most often has a bluish or grey colour. These colours are
also often shown very plainly on the roads where the rock has been worn bv
the traffic, and in a still more striking wav in the pieces that have been broken
out of the cliffs by the force of the waves and have afterwards been rolled about
and rounded on the sea beach. Hence the common local name for the hard
rock from which these pebbles and boulders have been formed is" blue-beach."
With some interesting and important exceptions to be noted later, this is the
rock which we shall find from Christiansted eastwards, throughout the easicrtt
trianoic and also throuafh the northwest district of the island ; but if we take
our specimens from the neck which intervenes between those two parts, or, to
speak more accurately, from the Central Slope, we shall find something very
different. Here the rocks are mostly white or creamy in colour. Sometimes
thev are soft and are known as marls, sometimes they are hard and are called
limestones, or locally, "marl-stones." In either case it is easy to see that they
must be placed in a quite separate class from the blue-beach rocks.

Before proceeding further, however, it should be noted that the word
"rock ". is used by geologists in a peculiar sense. While in daily language a
"rock " means a mass of liard stone, in geological language it means any mass
of material that goes to make up the crust of our earth ; hence beds of sand

h THE ISUILniNG OK AN ISLAND.

and clay and soft marls arc included among rocks, as well as limestones, grit-
stones or granites. It is in this more general sense that the word is used
in these cliapters.

The Two Rock-Fokmations of the Island.

We find then in the island two great classes of rocks, those which belong
to the '' bliie-bcack" set, and those which belong to the marls and limestones.

That there is some essential difference between these two classes of rocks
may be shewn in a very simple wav^ We take two glasses, each containing a
little diluted muriatic or other acid, and into one of them we drop a "blue-
beach " pebble, while into the other we drop a fragment of limestone, and we
see that the limestone immediately begins to effervesce while the blue-beach
remains nearly or entirely unmoved. What is the reason for this singular be-
haviour on the part of the limestone? It is that the stone is for the most part
a combination of lime with carbonic acid gas and that the latter is released by
the action of the aciil and comes awav in bubbles. The blue-beach pebble
behaves differently because it is (|uite a difTerent substance, being for the
greater part a combination of the substances which make clay and quartz.

It is plain then that we have two great classes of rocks in the island, and
we shall see later that, although the histories of these two great divisions are
in some respects alike, their modes of origin are for the most part very
different.

Stratified Marl Rocks, Anna's Hc^pi-

THE l;i II.DINC OK AX ISLAND.

CHAPTER II.

The Limestone and Maki. Formation in the Centkai, Slope.

The Central Slope of the island is occupied by the hmestone and marl
formation, which also stretches along the southwestern shore to the west end
of the island. We shall see later that it is the youn<i;er of the two great form-
ations which make up the island, namely, the nuxj'l and the '• hhic-bcachr and
that it rests upon the latter. The soil over the marl formation sometimes, and
especiallv on the hillslopes, has a whitish appearance, and very often contains
numerous stones broken out of the formation in a way to lie studied later.

The formation mav l)e examined wherever it has been l)roken into, eitlier
naturalh' or artificiallv, as, for instance, artificiallv in road-cuttings and quarries,
and naturally in sea-cliffs, watercourses and the like. We begin our study with
a road-cutting at .Xnna's Ilope estate, which is jiarticularlv suitable because it
is easily accessible from Christiansted. Here the road is cut in the hillside,
which gives us an opportunity to learn of what stuff the hill is built up. If the
study is quite new to us, the first thing which will strike us will probably be that
the rocks shewn at the roadside are arranged in layers, and the (|uesti(in will
arise, how is that to be accounted for? Whatever their origin there can be no
mistake about the fact of the existence of these layers, some of which form at
this spot, as shewn in the accompanying photograph, natural steps in a path cut
into the hillside and le;iding u]) to the estate residence. A furt her examination of
the layers shows that some are softer than others, so that the weather acting on
them wears them back and leaves the harder ones prominent. To proceed further,
we ought to have a jiocket lens'-' with us, and if we then break off a small piece

* A useful lens can be had from any optician at a cost of from two to five shillings ; but if the reader
is willing to spend something more on this most valuable little instrument, he is recommended to procure
one of the platyscopic lenses made by Mr. John Browning of 7S Strand, London, and costing fifteen shillings.
These lenses are made in three powers, and the cut shows the three forms, the most useful of which is the
one of lowest power (the largest lens shewn in the cut), which multiplies the image of the object
10 diameters.

Fig. 7.

The present writer has used one of these lenses for many years and has found it a source of great en-
joyment in the examination of the rocks and other natural objects in the island.

lO TIIK mnLDlXG, OF AX ISLAND.

of the hard rock with a hammer or a handy stone, we shall probably fmd, on
examining the broken surface with the lens, that there are minute shells in it,
so small that they can be seen only with the help of the lens. These small
shells are globular and are often filled with lime, so as to look like tiny balls.
We perhaps think, as we look, that we should like to get them out of the rock
so as to study them more easily; but this would be difificult. As we look
around, however, we shall soon discover a hint that Nature has already done
the work for us; for the weather, acting on parts of the rock, has reduced them
to a fine powder, which we find lying on the hard ledges that have better
resisted the " weathering" process.

Some of this powder we take home with us for examination, and we soon
find that in its present form we can learn very little from it, a good deal of it
being a fine dust which obscures the character of whatever harder grains the
powder may contain, "a fact which suggests that the first step is to wash away
that fine dust. This is best done in a small glass saucer, preferably of a dark
colour, or if of colourless glass the saucer may be placed over a dark fabric of
some sort for the examination of the contents. A small quantity of the powder
having been placed in the saucer, several washings will be necessary, the milky
water being poured off each time, after which we shall see that we have a fine

NOTES ON THE SHELLS SKETCHED ON PLATE B.

([.—The globular shelLs are very abundant. Although found in the present oceans, they are not, as far as
known to the writer, found in the shallow waters around St. Croix, but it is quite possible
that they exist in the deeper waters outside the bank. They are generally one-fortieth of an inch or
less in diameter.

/;. — Commonly composed of a growth of three to five united balls.

c. — A pretty shell found rather abundantly at Bethlehem and elsewhere. The margins are translucent.

/i-£'. — Similar, but apparently distinct species. The largest, "^," is one-tenth of an inch in length. The
kind "d" is abundant in one of the layers exposed at Anna's Hope.

/^— Found at Anna's Hope ; the thirtieth of an inch in diameter.

2. — May be compared with the forms 2 and 3 below.

/C'. — May be compared with the form 8 below. Near the old mill, west of Barren Spot, a similar form
with a convex base is abundant.

/. — Found at Anna's Hope ; one-fifteenth of an inch in diameter.

w. — A minute pearly beauty from Anna's Hope, the sixtieth of an inch in diameter.

I. — One of the commonest species in the sea-sand, varying very much, apparently according to age. The

dots in the upper part are intended to indicate the positions of some of the tiny chamberlets which

form the entire shell, and in some cases are plainly seen, while in others they are hidden by the

thickness of the porcelain-like shell. The whole shell is about the twentieth of an inch across.
2 and 3 are forms known as Miliolina (compare "/'" above). No. 2 is a plain shell, but No. 3 is prettily

ridged.
4. — A rare shell from Christiansted Harbour, the nearest to the straight kinds (compare "</" to "^"

above) found by the writer in present-day sand.
5, 6, 7. — Coiled shells, which compare with "/;' " x" and " w" above.
8. — Conical shell (comjiare "i" above),
g. — Fragment of a very beautiful flat shell, about the twentieth of an inch in diameter, which may not

unfrequently be found alive adhering to the flat blades of the sea-grasses. The shell is so trans-

pai-ent that the chamberlets show as dark spaces on a white ground and the whole shell, as seen

through the lens, resembles a beautiful piece of lace.
10. — A .shining, porcelain shell, the curved lines in the sketch representing .shadings in the shell.
II. — A rather common shell in the sand. It is about the thirtieth of an inch in diameter, and is built up

of a great number of tiny chamberlets, which in slightly water-worn specimens show as minute

holes crowding the surface.

B.

TlIK BUIT.DIXC OF AX ISLAND. II

siiinl left in the bottom of the glass. Pouring a little clear water over it so as
to cover it, we then examine this sand with our lens, and we gel some interest-
ino- results. Among a multitude of sand grains, of various si/es, we shall find
some, or perhaps manv, of the round shells which we first saw in the solid rock,
and we shall also from time to time meet with other forms, some of them very
heautiful, others onlv odd ; look, for example, at the beautiful coiled forms
sketched on Plate H. and near them the curious jointed form resembling a
sugar-cane.

These tiny shells are the remains of minute creatures caWg^X Foraminifcra,
and are found in most sea-sands. Hence, our examination of the marl rocks
lias alreadv shown us that thev'were built up in the sea. B\' wav of making
the matter certain bevond all dispute, however, we may compare the forms
which we get out of the rocks in the manner al)Ove described with the forms
which we get from the bottom- of the present sea. This comparison is made
in the accompanying Plate, where the forms, roughly sketched in the upper
half, are those of foraminiferous shells from our marl and limestone rocks,
while the forms sketched in the lower part of the Plate are those of similar
shells found in sand taken from the bottom of Christiansted Harbour or
other shallow waters around our shores.

These minute shells in the rocks are found not at Anna's Hope only but
at manv other places on the ishuid where the marl and limtsione formation
shows itself. The globular shells in particular are very abundant, and some of
the others also in special localities, while others again are rare and have to be
searched for. At all events, these interesting little shells are sufficiently
spread through our marl formation to prove that it has in all parts the same
origin, namelv, that it has ever\\vhere been built up, layer by laver, in the sea.

About the Foramixifera.

Having rendered us so important a service, these shells may, tor a brief
spact-, claim attention to their own history. Thev were once the tenements
of living creatures, as their representatives in the ])resent age now are in the
oceans and seas known to us; and the study of the existing members of the
family enables us to understand those which are extinct. Some species,
indeetl (the globular shells, for example), are both ancient and recent, being
found as shell remains in the rocks and likewise as living creatures in the
ocean.

Zoologists class all these minute animals as belonging to the Protozoa
(tirst animals), so named on account of the apparent simplicity of their
structure. Mainlv thev appear outwardlv to be tinv i)ieces of living jellv, by
which the shellv substance is deposited. By this tleposition a small cell or
chamber is formed. Some kinds never, or seldom, advance be\ond this one-
celled condition, but nearlv all kinds go on adding new cells to the first.
Some add the cells in a straight, or mavbe slighth' curved, line; but the
majoritv of the species add the cells in a distinctlv curved form, either a tlat

THE BUII.DTXG OF AN ISLAND.

coil or a spiral, that is to sav. ascending- like a screw; in a few species the
extension is started on the circular plan and continued on the straight; some
again add the cells in a succession of rings, one outside the other; anil some
add them alternatelv from side to side, suggesting the idea of their having
been interwoven.

How do these little creatures live? Some kinds, those with the globular
shells, for example, have the shells perforated with a great number of fine
holes, through which long gelatinous threads are protruded from the body,
and with their aid the animals catch the extremely minute particles of food by
which thev are nourished and from which thev obtain the lime for their shells;
with their aid, also, thev move about in the seaweeds, among which they live.
Most of the kinds, however, are not perforated in this way, but have apertures
in the last or latest-formed cell, through which similar threads protrude; the
other cells are connected with this one and with each other by a small hole,
and this enables all \rarts of the tinv creature tt) remain in living connection.
It is the possession of these minute holes through the cell-partitions that gives
the whole famil\- its name of Foramixifkra (bearers of small holes).

Contributors tcj the Sea-sand of the Submarine Santa Cruz.

We mav now leave the consideration of these shells and push our
inquiries a step farther. The foraminiferous shells found in the layers of the
limestone rocks, prove for us that these layers have been built up from the
sea bottom, but, except in regard to the generally small proportion which they
themselves contribute, they do not show us 0/ what the rocks have been
built up.

The comparison which we have just made of the foraminiferous shells
found in the rocks with those found in the sand of the great shallow that
extends around a large portion of our island (the submarine Santa Cruz, as we
have called it) suggests at once, however, a method of procedure; it suggests,
namelv, that bv stud\ing the story of the sand now forming along our shores
and in our shallows, how it originates and how it may be converted, and some-
times actuallv is conxerted, into stone, wc rna\' find the solution of our
problem.

The sand on \\\v banks and in our harbours is often called coral sand, but
the name is hardly justifiable, since the corals make but a small contribution
.to this sand ; still the corals add considerably to the bulk of the accumulations
on the sea bottom and are well worth attention. Small corals arc found in
many places, but the larger ones belong mostly to the reefs. These reefs are
submarine ridges or narrow banks built up of coral and sand. A glance at the
map will show that most of our reefs are not situated along the edge of the
great bank of sand, but at some little distance within it. The Long Reef at
Christiansted, however, and the reef at Buck Island are both not very far from
the bank's edge As already said, the reefs are mainly built up of coral. What
is coral ?

THE liUII.DINC; OF AN ISLAND. 1 3

In a tropical island like ours many forms of it are familiar to a visitor to
the beaches ; but a cursory examination of the dead specimens will not enable
us to understand their nature. In school books \vc sometimes fmd the praises
of the "coral insect" sung as the industrious builder of islands; but, as a mat-
ter of fact, there is no coral insect, neither does the living coral "build" in
any proper sense of the word. To understand what a coral is we must first
study the -animal llowers " tliat we find along our shores. It is true that
some of the most beautiful oi these, namely — those which spread out their
"petals" from the tops of tubes and are quick in withdrawing them, are
worms,'"" and have no familv connection with the corals ; but the fleshy ones
with stickv arms around their outer edge (sea-anemones) are first-cousins to
the corals. Most of these animal-flowers live separately ; but on the reefs,
and occasionally along the shores, too, a form of these curious creatures may
be found which live in extensive colonies, the bodies all joined together by a
sheet of flesh below, the upper parts showing as pretty stars with green cen-
tres, closely packed together, forming a beautiful piece of natural carpeting.
This form carries us very near to the corals ; for if we now think of the stars
as still further reduced in size, and think of them and the fleshy sheet which
unites them as depositing a limestone foundation, we come very near to a
clear conception of what a coral is. When we see the stars on the stony coral
we now know that they were deposited below the stars on the living animal.

A live coral, then, is a compound animal, feeding its hundreds, or may be
thousands, of little stomachs on whatever suitable food the waves may bring
to them, and feeding them with the help of the star-like sets of tiny arms that
wave over the gelatinous surface, while, as the whole grows, carbonate of lime
is deposited below and in the partitions which go from the outer wall of each
ceH towards its centre. Thus, the living coral does not din'/d the stony base,
or the stars, any more than a child builds the bones in its body. In both cases,
that of the child and the coral alike, the stony material is extracted from the
food and lodged in its proper place by the vital processes.

The creatures mentioned above constitute the family of the true corals.
There are, however, closely allied kinds which form hoimy skeletons, such as
the well known yellow sea-fans and purple sea-fans, and the branching sea-rods,

* Some of the sea-worms of the West Indian shores are among the most beautiful objects in creation.
The large Sabella, for example, that inhabits the Lagoon at Christiansted and may occasionally be seen
along the shores of the harbour, suggests, with its corolla-like fringe of breathing organs coloured in con
centric bands of brown and white, a large and beautiful chrysanthemum. There are other beautiful but
smaller kinds, for instance, a bright yellow one always in motion, swinging its arms to right and left in
regular time ; another, a brown one, that peeps through the sand in groups, and is so sensitive to light and
shade that merely passing the hand over the water above it causes the instantaneous withdrawal of the
"flower" into the tube. None of these, however, contributes anything to the materials accumulating at
the sea bottom, their tubes being simply leathery. On the other hand, there are some kinds which have
hard, shelly tubes, and fragments of these may often be found in the sea-sand. There is, for instance, the
curious brown Serpula. which coils itself in masses over the rocks, and sometimes becomes an actual pro-
tection for them. There are others again which form very small shells, flat white coils that may be fre-
quently found adhering to stones and other objects in the shallow water. Both of these kinds occasionally
contribute fragments to the sea-sand.

14 THE BUILDING- OK AN ISLAND.

all of which arc covered with a fleshy coat in which the small stars are em-
bedded, a coat which contains some lime, and this frequently in delinite forms
that may be often seen as grains forming part of the sand of the seashore.

Another stonv form that exists on the reefs, and on some of them in
great abundance, is the viillcpore coral, of which the naturalists tell us that the
living creature that covers it and occupies the thousands of tinv holes which
give it its name, does not belong to any of the great groups above mentioned,
but forms a class bv itself. Like the true corals and their allies, it contributes,
however, to the material forming the sea bottom around our shores.

The corals of all kinds contribute, however, only a comparatively small
portion of the materials accumulating on the surface of the submarine Santa
Cruz. An examination of the bottom with the aid of a sea-glass will help us
to understand how the sand which covers that great area has been formed, and
how it is continually increasing. The glass in question is simply a watertight
box open at one end and covered with a sheet of glass at the other; the glass
being pressed down on the surface of the water gets rid of all the small ripples
which ordinarilv prevent our seeing what is at the bottom, and then every-
thing, corals, seaweeds, sea-eggs, starfish, or whatever it may be. becomes
quite distinct. We mav also learn much by taking up samples of the sand
from the bottom and from the seashore, and examining them with the help
of our lens.

We shall find that the sand is supplied by many living agencies, which in
turn obtain the material from the clear sea-water. Among many other sub-
stances dissolved in it, the sea-water contains carbonate of lime. Many sea-
weeds have the power of extracting this carbonate of lime, and some of tiiem
in such a remarkable degree that thev come at last to be almost entirel\ com-
posed of it. When they die and break up they form a large proportion of the
sand in some places, for instance at the Round Reef in Christiansted harbour,
where one well-known seaweed is verv conspicuous as a component of the sand.
Other lime-loving weeds have some general resemblance to corals and are
known as " corallines"; others again, which mostly encrust rocks, resemble en-
crusting corals, but from possessing no openings have been called " nuUipores."

Sea animals, feeding on the weeds, find the lime for various parts of their
bodies, as the shells of molluscs, from the gigantic conch down to the tiny
limpet clinging to the rock on the shore, or the shells and spines of sea-eggs,
or sea-stars, foraminiferous shells, the shells of crustaceans, and so on. All
these creatures, at their death, whether violent or natural, leave the solid parts
of their bodies as a Icgacv to the sheet of material forming on the sea bottom. ••■■
When such remains are near the shore thev are driven upon it and are broken
by the action of the waves into coarse or fine fragments, or are even ground

• The following notes of the contents of a sample of sand taken by the writer from the beach at Cane
Bay on the north shore of the island will serve to show how varied are the sources of our sea-sand. The
sample was gathered at the wave-margin, and is not so worn as the ordinary beach-sand at the same spot.

The following was the compo.sition of three small portions examined, the grains being separated i^artly
with and partly without the aid of a lens : (See ne.xt page).

THE BUILDING OF AN ISLAND. 1 5

into powder, f some of the fragments or the powder again drifting out into
deep water. In such ways as these the sand at the sea bottom is continually
being increased. Some part, it is true, is again dissolved, as we shall presently
see, and part of this may be lost, so far as the material at the sea bottom is
concerned, but the bulk of it remains, and so year by year the surface of the
great bank is being slowly but certainly raised, and the thickness of the bed of
material accumulating at the bottom is being slowly but certainly increased.

Contributors to the Limestone Formation.

We may now turn to our marl and limestone rocks to look for further evi-
dence than that of the foraminiferous shells as to whether their origin has been
similar to that of the sand of our present seas. Without leaving the Anna's
Hope rocks we may already go a little farther than the evidence of the fora-
miniferous shells will carry us, for w.e will find here an occasional coral, and at
least one bed containing the spines of sea-eggs. Here also, in a cutting, on
the southeast side of the road and looking southeast, there is found a laver
which to some extent departs from that mode of origin, for it contains a
number of pebbles and some sand derived from the older formation. It is
worth while to pause and study this fact a little more fully, for the same thing
may be observed in many other places, and it has an important bearing on the
question of the origin of the soils covering the marl formation. The pebbles
are nearlv all rounded, as on a beach, an indication that they have been brought
down from the ancient land into the sea where the shell-sand was beincf accu-
mulated and have been rolled about on its shore before being finally buried.

ORIGIN. , NUMBER OF GRAINS. TOTAL.

No. I No. 2 No. 3

\ Fragments o£ Nullipore (mo.stly red) 14 34 27 75 )

VEGETABLE j '• " Calc. Weed (Halimeda) 7 24 13 44 [- 155

( " " Corallines 3 23 10 36 )

Foraminiferous Shells (whole and fragments) ig 47 34 100"

Shells, molluscous (mo.stly fragmentary) 6 21 15 42

ANIMAL . . .-i, Fragments of Echinus Spines 3249 ,

I " " small crustaceous Shells i o i 2

I Minute Serpula Tubes ' 0314

I^Fragrhents of Echinus Shell o i o ij

Agglutinated Grains (same substances) i 6 9 16

Not determined . S 14 11 33

Totals 62 175 125 362

t If we examine with a lens the ordinary sea-sand on an open coast we shall find that most of the sand
grains, though obviously fragments of molluscous shells, sea-egg spines, nullipores, or the like, have a
rounded form and are beautifully polished, and we can easily see that these peculiarities result form
their being ceai5elessly rubbed against each other as the waves come and go on the shore.

We can further see that a fine powder must in this way be continually rubbed from off these grains,
and if we do not find this powder among them, it is because the sorting power of the water carries it away
and lodges it farther from the shore.

After having observed these facts and drawn the plain inferences from them, we need hardly ask for
any further explanation of how it is that we find so much finely divided material among the rocks of our
limestone and marl formation. Even without allowing for the effects of subsequent changes in the depos-
ited materials, the beach history of a part of them would give a sufficient answer.

l6 THE 1UII,])IN(; OK AX ISLAND.

We mav find a prcscnt-dav illustration of this ancient process hv noting
what takes place in Christianstcd and the neighbourhood on the occurrence
of hcavv rains : the streams from the hills liring down large <|uantities of fine-
mud, sand, and even pebbles, and lodge them in the harbour. Even in the beds
of stone formed on our Long Reef, in a way to be noted later, we mav find a
few minute pebbles, which perhaps have been carried there attached to debris,
such as dried seaweed on the beach or uprooted weeds and bushes which have
drifted out from the land. Returning now to our search for evidence as to the
regular contributions to the Marl Formation, we find that somewhat similar
sections to that at Anna's Hope mav be seen, on a smaller or larger scale, at
several other points, witliout even leaving the eastern edge of the Central
Slope, and in some of them we shall find abundant evidence of the kind we are
looking for.

The most important of these sections is at Cane Garden, wiiere the rocks
aie cut into bv the sea and form a low cliff for a considerable distance along the
shore. The lavers here are for the most part alternatelv soft and hard, the
soft layers often sandy and containing numerous foraminiferous shells and the
spines of sea-eggs, the hard lavers generallv containing the moulds of finger-
shaped corals, that is to say, the corals themselves have disappeared, have, in
fact, been dissolved out, while the sand or mud which surrounded them has
kept the impression of their forms. This is a remarkable change, but it is one
which is verv common in limestone rocks. Occasionallv, where a shell has
been dissolved out, a east of the interior remains; thus we may sometimes
meet with casts of volutes, and several kinds of bivalve shells. It seems also
that this dissolving out of parts of the limestone and its later solidification in
other spots has had a large share in tlie process of hardening, which has
taken place in the beds after their deposition as loose sand and mud; it has also
been the cause of the concretiois which will be noticed later. That the large
beds are sometimes broken through by a number of cross cracks, so as to re-
semble a building up oi separate blocks, is i)erhai)s caused bv contraction after the
hardening has taken place. This peculiarity is known by geologists as " jointing,"
and is bv no means uncommon in the marl formation, though, as we shall see
later, it is much more marked in the blue-beach formation. Thus the section of
rocks at Cane Garden is a \-erv instructive one, for not onh' have we a great
number of beds piled one ovei- the other to a thickness, as measured bv the
present writer, of over 200 feet, but we learn that great changes have occurred
since the deposition of the material which forms these beds, changes wiiich
have been carried vi-rv far in the u])per ])art of the cliff, where the weather has
acted on the beds to an extraordinarv degree, so that all traces of the original
lines of stratification disappear, and the whole of the part afl'ected is converted
into a rather soft white marl; not only so, but this surface marl, owing, no
doubt, to expansion and contraction, as it becomes wet or drv. according to the
seasons, splits into irregular sheets roughlv parallel to the surface of the soil.
In this wa\ a false stratification arises, which ma\- often be seen in road-cuttings

Casts of V'ulutes frum Montpellier East, Others from Quarry South of Frederiksted.

THE HUILDINC OK AN ISLAXIJ. 1/

and like places, and nii^ht easily mislead an inexperienced observer to record
it as true stratification. After, however, he had seen thi' lines follow the surface,
even on tht' slojies of a hill on both sides, he would suspect it, and the t'xanii-
nation of a section like that at Cane (iarden would make the whole matter
clear. It has already been noted that the Cane Garden cliffs present alterna-
tions in the beds; in some of the layers we have the sea-sand with its minute
shells and spines of sea-eggs nearly as the whole was deposited; in others,
alternating with these, we see that the rocks have been hardened, while the
corals which they had contained are indicated by hollows only, the sid)stance
of them having been dissoKed away. If we ask why there should be these
alternations in the strata, it is only possible to reply in a general way that the
conditions must have been continuallv changing, a general statement which
admits of clear illustration, however, by taking a case from our harbour. Just
inside the reef itself several shoals have been formed, and some of these consist,
on the top at least, of finger-shaped corals, some alive but most of them dead.
It is plain that this layer of corals must rest on something else (sand, for
example), and if the surface conditions should later be changed the coral layer
would in turn be covered by a different accumulation. Now in the limestone
rocks at Evening Hill, west of Christiansted. a similar accumulation of finger-
shaped corals in beds mav be found, so that we have the ancient accumulation
and the modern accumulation not far from each other, the latter enlightening
us as to the origin of the former.* We may say then, that the hnver part of
the Cane Garden section, read in the light of an illustration from elsewdiere,
gives us a good deal of the history of our limestone formation, white the upper
part, as shown above, throws light on recent changes which io a large extent
obliterate the earlier record.

Thinning Out.

In connection with the above a condition which mav sometimes be seen in
a layer in a (|uarrv or roadside cutting should be mentioned. It is sometimes
noticeable that a layer does not continue through the whole length of the cut-
ting, but becomes gradually thinner and finally disappears, leaving the layers
below and above it to touch each other. An example may be seen at the cutting
to the south of the road at Anna's Hope, where a bed of fine gravel //i/ns out in
this way towards the southwest. If we could see the whole of our limestone
beds it is likelv indeed that most of them would be found to thin out before
they had extended over anv large area; that we do not more often see it arises
from the beds being generally exposed for rather short lengths.

* It may be noted in passing that these Evening Hill rocks are of special interest, on account of their
containing the largest species of foraminiferous shell found on the island, and found, as far as the pre.sent
writer is aware, at this spot only. The shell commonly measures about a quarter of an inch acrcss, is round
and flat, with a bulge in the middle.' It contains a great number of very small oblong chambersor rather
chamberlets, which make it an interesting shell to examine, and it has a special scientific interest in con-
nection with the determination of the age of our limestone rocks in the world's geological history.

l8 THE BUILDING OI<~ AN ISLAND.

t

Conclusions lrOxM the Foreooini; Ouservations.

Pausing now to sum up the results of our observations thus far, we see
that in the quarries and road-cuttings on the hillsides, as well as in the clifTs of
the seashore, the peeps which we get at what is beneath our feet in the district
studied, show that the whole great mass of the land has been built up, laver
after layer, in the sea-bottom by the gradual additions, we might almost say
grain by grain, which countless living creatures, both animal and \egetable,
have made to it tlirough long ages. If we could remove the verdure and the
soil from the landscape, we should see all the hills and the valleys, showing
the creamy white colour and the arrangement in iavers, of which we have only
been able to get glimpses here and there, and we should see plainlv that tlie
whole had one common origin. This building up of our limestone formation
beneath the sea and from materials extracted from the sea-water is, then, the
first great fact that we have learned.

Another great fact presents itself, and it is an obvious one ; either the
level of the sea has been lowered or the whole mass of this accumulated
material has been lifted considerablv since it was deposited in the ocean. As
we shall see later, there is good evidence for the lifting, and it has been so
considerable that some parts of the formation are now 400 to 500 feet above
the sea level, and at one point, near Bulow's Minde, the height is over 600
feet. Such elevations must have been reached by a great movement, or series
of movements, implying the action of great forces ; and we must also remember
that the base of older rocks, on which all these limestones and marls rest,
must have likewise been pushed up. This base we have so far scarcely thought
of, but we have regarded it as if it were merelv a solid block on which the
younger formation rests, and at present it will suit us to continue to think of
it in this wav, so as to confine our attention to the younger rocks. Still we
must not forget that any great movement, of which we find evidence in the
upper rocks, must have been shared by the lower rocks; if we see that the
limestone formation has been upheaved, then the blue-beach formation, on
which it rests, must have been upheaved along with it.

Slope of the Beds.

Studying the great upheaval of whicli we have seen such plain evidence,
we perceive at once that the strata, although laid down, no doubt, horizontally
in the sea, or nearly so, have not kept that position during the upward move-
ment, for we have noticed at the places on the eastern edge of the Central
Slope, where we have examined the rocks, that the layers slope away, or dip
as the geologists say, to the southwest, and this will be found to be the case
along the entire eastern edge of the Slope; at Bulow's Minde, Constitution
Hill, Anna's Hope, Work and Rest, Granard and Cane Garden the slope is
to the southwest or thereabouts. The amount of the slope is not insignificant
either, but varies from 5 or 6 up to about 15 degrees.

'IIIE nUlI.DINf; OK AN ISLAND.

19

As \vr shall find later, this question of dip takes a very important place in
the studv of the history of the rock formations, and is, therefore, worth special
attention. Occasionally the layers are horizontal and then there can he no
question of dip; hut commonly this is not the case, the rocks generally slope
in some definite direction, that is tf) say, towards some definite point of the
compass, and this is noted down as the dip; the layers mentioned ahove, for
example, have a souihwest dip. The amount of the dip is measured in angular
degrees from the horizontal, and after a little practice we can generally tell by
the eye alone the approximate amount of the dip; hut if we wish to measure
it more accuratelv, we must use a simple instrument called a clinometer (slope-
measurer). Such an instrument can be bought from an instrument maker;,
but may also be constructed at home on a card with sutlicient accuracy for
amateur purposes. The figure below shows such a home-made clinometer.

The Card A B has a semicircle drawn on it, on the edge of which the
degrees from one to ninetv are marked off on both sides in an upward direc-
tion, starting at D. From the centre C a small shot is suspended by a thread,
and the lower edge of the card is applied to the layer of rock. The shot, of
course, hangs perpendicularlv antl shows the angle at which the layer under
examination slopes from the horizontal. As the beds of rock often present a
rather rough surface, it will be found convenient first to rest a straight stick
along the rock in the direction of the dip and then to apply the clinometer to
the stick, instead of to the rock itself.

20 THK KUII.DING OF AX ISLAND.

Tlie line which runs at right angles to the direction of the dip, or, in other
words, the line which lies horizontally on the sloping rock-surface, is called the
line of strike, or sinijily the strike. At outcrops — that is to say, at places where
the rockv layer crops out, or appears naturally at the surface of the ground, it
is sometimes easier to take the strike than the dip. When the strike has been
found a very small exposure will give us the direction of the dip, which is at
right angles to it ; hut the anioiud of the di]) remains to he observed.

Usp: ok the Co.mi'ASs.'^'

To find the direction of the dip we must use a pocket compass, an indis-
pensable companion in our exploring expeditions, and since the cutting we
examine may cross the rocks in any direction, some caution is necessary in
noting the direction of the dip. It is seldom that a cutting or quarry will jire-
sent a face of rock which at once shows us the diji, and we have to observe it
on projecting corners, where such can be found, or estimate it from what we
see on rock faces having different directions. After a little practice the ama-
teur will find it fairlv easv to get the strike and dip of the rocks in anv section
exposed.

In. recording the strike and dip on a map a short straight line is used to
show the strike, and another springing from its middle point at right angles
shows the direction of the dip ; the amount of the' dip may be recorded by the
length of the line, which should be long for a low dip and short for a high dip,
or both direction and amount mav be entered in letters and figures close to
the line.

But to return to the southwest dip, which wc found to be prevalent all
along the eastern edge of the Central Slope, we naturally ask whether the
same dip is to be found over the whole of this slope? If not, to what extent
does it prevail, and what regulates it ? We have noticed that the tilt is from
the east side, where the hills of the Eastern Triangle commence, and it per-
haps occurs to us that on the western side of the Central Slope, where the
rocks rest against the hills of the IVcstern Oblong, it would not be surprising
to find a corresponding tilt from that direction— that is to say, from the ivcst,
and on examining these rocks this is just what we actually do find. For if we
study the layers exposed at different points along the tvestern edge of the

* A poclcet compass can be purcliased for about half a crovvu or 3 francs, and will be found useful
for other purposes besides finding the directions of the dips.

There is a very remarkable fact in connection with the compass which ought here to be noted, not-
withstanding that it has scarcely any practical bearing on observations taken in St. Croix, and that is its
variation. It happens that in our island the magnetic needle points very nearly to the true north, but in
many other places it deparls considerably from that rule. In northwestern Europe, for example, it points
to west of north, the variation being in Denmark about 12 degrees and in England 16 to iS degrees. Here
in Santa Cruz the variation at present does not amount to two degrees, say the forty-fifth part of a right
angle. It is necessary to say " at present" because it is slowly increasing year by year, the annual addi-
tion being at Santa Cruz about 3 minutes, or say. the twentieth part of a degree. In the distant future,
therefore, it will be necessary, even for an amateur, to make allowance for variation, though at present it
is too small to be, in ordinary observations, of any practical conseciuence.

THE r.UlLDlXc; OK AN ISLAND.

2 I

Central Slope, at Montpellier, Morning Star, Bonne Esperance, La Rcine and
Barren Spot, wc find all these layers sloping, not to the southwest, as we found
those of the opposite side, but to the southeast. We find this same dip also '^
in the pieee of the marl formation across the valley and resting directh' against ^^
the Salt River Hills — namely, at the estates Windsor and Concordia. It is
also interesting to notice that the amounts of the dips of this new set are
about the same as those of the set previously examined. It appears, then,
that if wc could cut the beds of the Central Slope through from east to west
we should see them sloping inwards from the east and the west towards some
central line where they would meet, a line which geologists call a synclinal
axis, the whole arrangement of the rocks thus sloping together being called
a syttclinal. The case may be easily represented by partially- opening a book,
when the leaves to right and left will represent the sloping la\ers of rock,
forming the synclinal, and their junction down the middle will represent the
synclinal axis. If we further give the book a tilt from one end, calling it the
northern end. we shall get a still closer representation of the case before us,
for we have found that the rock layers do not dip in from due east and west,
but on both sides have an inclination also to the south. The diagram shows
how the limestone layers of the Central Slope rest on the older formation. It
will, of course, be understood that the black and white bands in no sense rep-
resent the layers. They merely indicate the slopes of the system.

How TO Find the Synclinal Axis.
To tind where this synclinal axis runs is a task of no great difficulty, and
is of very great interest. The obvious plan to pursue is to cross the slope
along several lines going east and west, and to note on a map* the dip of the
rocks at every place where we can see it till we get, at all events, the approxi-
mate position of the line we are looking for. If we commence with the road
along the Princess plain, we find, at Belle Vue and the hills around, several
quarries and small road-cuttings, all of which show dips to southwest. At Big
Princess we find the same, then a southerly dip, and, at a cutting in a range
due south of St. John's residence, we find a dip to south-southwest ; but at
Montpellier and Morning Star, as well as on a road ascending the hills east of
the former place, we find that the dip is southeast. Hence wc see that the
synclinal line passes somewhere near the Estate St. John's. If we take the
road along the top of the hills ascending from Belle Vue we find a similar
condition ; the road-cuttings shew dips to the southwest until we approach the
turning where the road goes south to Rattan, and here the dip is southeast.
Along the roads which cross the Central Slope more to the south we find
southwest dips till we reach the neighbourhood of Diamond and Ruby; but a
short distance farther on we find at Barren Spot southeastern dips on the west
side of the village, and it is plain that we have crossed the synclinal axis.

* The reader who may wish to follow up this investigation for himself should procure one of Captain

Parsons' charts, or the chart of Santa Cruz, published by the Hydrographic Office, Washington, on which
to note his observations.

t>-

^!

\:l

u

c^

fc

22

THE IJUII.DINC OI-: AX ISLAND.

^

'^■'Wa-ou- / ^^\ < r^~- J'.

^

A .,^^|.,

Ot^/hai

jLp7^£"t^ ^^j^^t

/

Synclinal of the Central Slope.

TIIK BUILDING OF AN ISLAND. 23

When wc look for it on the east side of Barren Spot Village we find a soutli-
erh- dip, and as such southerly dips prevail on the line north from this position
it would seem that the axis must be regarded as lying along a narrow band,
across which the dip probably changes in a gratlual, but somewhat irregular
manner from southeast to southwest.

It is verv noticeable that the synclinal axis now traced does not pass down
the middle of the Central Slope, as we mav have expected after finding the dips
similar in amount on both slopes of the synclinal, but that it passes nearer to
one side than to the other, namely, nearer to the western than to the eastern side ;
but this apparent anomaly disappears when we notice that on the west side of
the Slope the limestone formation extends right across the valley that bounds
the Slope and even rests in a considerable mass (at Windsor and Concordia)
against the Salt River Hills ; whereas on the eastern side of the Slope the for-
mation ends abruptly on the tops of the hills belonging to the Slope itself. In
other words, the boundary valley on the east side has been cut out of the rocks
of the older formation, while on the west side the boundary vallev has been
cut out of the limestone formation itself. This is what gives the apparent one-
sidcdness to the structure, and it explains some other peculiar features of the
district.

It should be noted, however, at the same time that synclinals are by no
means always equally balanced ; but that it frequently happens that the two
sides differ considerably in their relative proportions, a fact which is indeed
exemplified, as we shall shortly see, in one part of this very synclinal which
we have been studvinsf.

24 THE BUILDINC. OK AN ISLAM i.

CHAPTER 111.

The Limestone and Maki, Formation oitside ok the Central Slope.

Having iidw taken a survey of the Central Slope and mastered the main
features of its structure, we may pass on to study the remaining portion of the
Limestone and Marl Formation, namelv, that which extends itself along the
southwestern coast district and around to the western shore. The beds at
Windsor and Upper Concordia must be excluded from this new studv, since
we have found that thcnigh apparently isolated, they not only dip in the same
direction as the rocks of the western edge of the Slope, but extend under the
valley so as to be continuous with those rocks; hence they must be regarded
as belonging structurallv to the Central Slope. At first sight it would seem
that we might suppose the same to be the case with the limestone beds of the
Kineshill Rantre. The rocks there, as at Windsor, are continued under the
separating valley, and when they appear at Kingshill we might expect them, as
at Windsor, to dip also to the southeast; but they do not; instead of that,
they dip at a low angle (sav five to ten degrees) towards the south, and in
some places even to the west of soutii.

This change in the dip of the rocks from soutiieast to south across the
narrow valley will be found to be worth a closer examination In our study of
the Central slope we saw that the synclinal axis passes east of the Barren Spot
Village, while just to the west of the village the rock lavers show the south-
eastern dip which belongs to the western slope of the synclinal. Vet only a
few hundred yards farther to the west (at the old mill on the rising ground
across the valley) we hnd the strata dipping to about southwest, and this rising
ground, wlierc such is found to be the case, is a jiart of the Kingshill Range.
Hence the west slope of the synclinal is at this point reduced to a very narrow
strip and in this respect presents a gre;U contrast with its width in the north,
where it stretches across from St. John's to Windsor and is a fair balance for
the wide eastern slope of the synclinal.

How i^ that ? Whv is the western slope of the synclinal, which is so broad
in the nortiL narrowed down to next to nothing in the south? The answir
api)ears to be, that a line of elevation passes down the Barren Spot valley
tiirowing the strata on tlie east side to the southeast and the strata on the west
side to the soutli, and just here to southwest; it also appears that tliis line of
elevation has not affected in the same wav the northern strata at Windsor, but
must lie outside of them towards the west. Searching for this line of eleva-
tion, called by geologists an anticlinal axis, our thoughts go back to the Mt.
Eagle Ridge. We remember how this ridge divides the waters coming from
liie noitiurn hills, sending off those on its east side to the nortJi coast and
those on its west side to the south coast. We also remember that the ridge
lies northwest and southeast, and if we prolong the line of its axis" to the south-
east we shall find that this line will pass along the Barren Spot valley; from
this vall(\-, in fact, tlie Mt. Eagle Ridge is seen " '.•\\(\ on."

THE BUILDINC; OK AN ISLAND. 25

It appears, then, reasonable to suppose that alonij this conspicuous ridjre
there lies an axis of elevation and that the later lifting movements have thrown
off the waters on either hand and have likewise tilted the beds of limestone
rock, so that on its northeastern side they dip to the southeast and on its
southwestern side to the south, or in some places to west of south.

To readers accustomed to studies of this sort the case will have been
obvious from the first, and it may seem that too manv words have already been
given to it; but for the sake of others to whom such studies are quite new it is
hoped that sonie further illustrations of the facts mav be permitted. We mav
again use the open book, with which the synclinal mmX the synclinal axis were
illustrated, only in this case the open book must be turned with its face to the
table instead of upwards, as usual; the leaves on each side will then represent
the strata of the atiticlinal and the back of the l)Ook will represent the anti-
clinal axis. As in the former case we may give the book a tilt from one end,
calling it the northern end, and if we further suppose a part of the back to be
cut away, we shall get a very fair illustration of the facts under review.

The sketch map here given will further help to elucidate the case; it shows
the position of the axis and the dips of the strata of the anticlinal (to south-
east on the one side, to south bv west on the other). In the accompanying
section across the Barren Spot Valley from one old mill tower to the other,
the dotted arched lines show the positions once occupied bv the upheaved
limestone strata, the higher parts of which must have been cut away to form
the valley and to leave the strata showing on either hand the edges which we
now see. The (]uestion how thcv have been cut away, how the arch lias been
so broken down as to be converted into a hollow, is one of exceeding interest
and will become more and more plain as we proceed with our enquiries.
Already we have seen hints elsewhere that there have been such removals of
the rocks on a large scale, but it is best, so far at least as these pages are
concerned, to leave this question for further consideration later.

If we now proceed to examine the west side of the anticlinal just con-
sidered, we find the whole block of low limestone hills, to which we have given
the name of the Kingshill Range, and which spreads south from Fredensborg,
to be made up of limestone strata having similar characteristics to the strata
of the Central Slope and all marked by dips to the south, as illustrated by the
open and turned down book.

On its western side this hill block is abruptly terminated by the water-
course passing the estate Bethlehem, and w^e might suppose that on tiie farther
side of the watercourse we should meet with a change of dip, but instead of
such a change we find the southerly dip continued through the low hill running
westward, on which are situated the residences of the estates Bethlehem and
Golden Grove. At both these places the dip is onlv a trifle east of south. In
other words, the influence of the Mt. Eagle anticlinal extends to some distance
to the west of the Bethlehem watercourse.

Proceeding a little farther west we find three other small and low limestone
hills to be examined. They are all separated from the small Bethlehem ridge

26

THE BUILDING OF' AN ISLAND.

Anticlinal Axis oi- Mount Eaglk Ridge.

THE BUILDING OF AN ISLAND. 2/

by the valley of the watercourse crossing the Central plain from the north-
west and joining the Bethlehem watercourse to the south of the residence. Into
these three hills the dip of tlie strata making up the iiill last described does
not extend.

Fir,. 12.

cwmut

.\~_^- --^^Z} Sfoirt

Section Across Barren Spot \'allev.
The dotted lines indicate position of strata presumed to liave been removed.

Starting from the east we find in the first of the three hills (a long low hill
on Bethlehem estate, south of the hill above mentioned), and in the second,
(the hill at Adventure) that the rocks dip to the southeast, while in the third
(the hill at Mt. Pleasant) the rocks dip to the .south, not, however, as a con-
tinuation of the southerly dip already mentioned, from which it is clearly
isolated. The probable explanation of these facts is, that an axis of elevation
passes through the northwestern block of hills from northwest to southeast,
and is continued towards the southeast between the hill at Mt. Pleasant and
that at Adventure, throwing tlie rocks off on either hand. Thus the rocks on
the northeast side of the axis form a slope towards the rucks of the Mt. Eagle
anticlinal, which they meet apparently in a synclinal axis that pretty nearly
follows the line of the Golden Grove watercourse. It 'is noteworthy that
while the hill at Adventure shews dips to the southeast, its southern end (at
Negro Bay mill-tower) shews a southern dip as in the strata at Mt. Pleasant.
It is this interesting fact which suggests the direction of the supposed anti-
clinal axis as being from northwest to southeast, the suggestion being
strengthened by the way in which the water is thrown off by the northwestern
block of hills, namely, to the southeast on the eastern side of the block, and to
the south on its southern side.

The Limestone FoK^rATION in the Plain.s.

With this survey of the four small hills in the south-central part of the
island our study of the hilly portion of the limestone and marl formation closes.
The surface of the rest consists of valleys and plains, namely, first the valleys
between the hills, then a part of the Central Plain, and lastly, the whole coast
plain stretching westwards along- the southern shore and along the western
shore to a little north of Frederiksted.

In the Central Plain the formation is covered by debris from the older
rocks, forming gravelly and clay soils, and masses of debris below these -soils,

28 THE BUILDING OF AN ISLAND.

often of considerable thickness. The presence of this covering makes it im-
possible to mark the boundary of the limestone formation across the plain with
anv approach to accuracy, so that the line laid down in the map has in that
part very little practical value. If it were required, for instance, to know how
far the marl extends under the debris northwards, so as to get at it for agri-
cultural purposes, it would be necessary to decide the point bv borings. Some
years ago a boring for a well was made near the Bethlehem Works, to the
north of the Centre-line Road, and after a few feet of debris, a thickness of 150
feet of marl was passed through; hence we are safe in carrying the line north
of the Bethlehem Works. A few hints further west enable us to carry it
along the north side of the Centre-line Road past Lower Concordia, and then
northwards l)ack of Frederiksted to the coast. In contrast with the uncer-
tainty as to the boundary over this plain, we find that the boundary around the
Central Slope is not difficult to fi.x and will be found to be verv ncarlv as laid
down in the map.

The plain country of the southwest affords only a few exhibitions of the
marl rocks in low cliffs (or vertical banks) on the seashore, and in shallow road-
cuttings here and there. At Betty's Hope and some other places these banks
contain a great number of verv hard limestone nodules of irregular forms,
apparently concretions or, perhaps in some cases, concretions that have been
partly rounded by water. The concretions may be seen in the shallow road-
cuttings and in the banks along the shore at Betty's Hope. At Long Point
the rocks contain a great number of impressions both of shells and corals, and
in some places the fossils themselves have been left. Neither in these cliffs,
although some parts are over 20 ft. in height, nor in the few shallow road-
cuttings in this part of the country do the rocks show any distinct stratification,
and it may be that they form a thick mass nearly or quite horizontal.

At Frederiksted we have the remarkable limestone already described.
The quarries are to the east of the town ; the strata are somewhat irregular
and much broken; they dip away at a rather high angle (about 2~, degrees) to
the west. Considering that the island ends abruptly along its western shore,
this steep dip to the west is very suggestive. It would appear that the lifting
force which brought up these rocks was greatest somewhere to the east of the
town. Where is that line of elevation, that anticlinal axis? It probably
stretches from northeast to southwest through the northwest hills, and is con-
tinued along the spur that comes down towards Concordia, ending in the long
point (Sandy Point) which stretches out at the southwest extremity of the
island. This view is strengthened by the geography of the marls in this part
of the island, namelv, their lying along the south coast on the east side of
the supposed anticlinal, and along the west coast on the west side of it, and
it is also confirmed by the flow of the surface waters from the northwestern
hills, namely, towards the south on their southern side and towards the west
on their western side.

At the entrance to the town of Frederiksted there are some beds of lime-

THE BUILDING OF AN ISLAND. 29

Stones and marls cut througli for the roadway. These beds dip at a moderate
anarle to about south-southeast. Thcv, like the beds below them, are full of
corals, but they appear to have been put down much later than the rocks in
the larg^c quarry. It seems indeed that the two sets are well marked off from
each other at West End, that the southerly dipping rocks have been put down
over the westerly dipping rocks, and have been tilted at a later time by a
movement from the north, the last, perhaps, of the movements that have given
the island approximately its present outlines. It is probable, moreover, that
the southern dip. mentioned as belonging to the upper rocks at West End,
docs not extend very far, but soon gives way southwanls to a horizontal arrange-
ment, which is what appears to prevail over the whole of the southwest plain.

It must be admitted, however, that the geological evidence for the sup-
posed anticlinal axis through the northwest hills and continued to seawards
through Sandv Point is not strong. It has already been mentioned that the
stratification in the big quarry on the east boundary of the town is irregular,
and when we examine the different small exposures south of the town and the
more important one in the large quarry near the north end of the Salt Pond,
the quarry at present being used for procuring limestone for the Central
Factory, we see no evidences of a westerly dip, or, indeed, of a dip of any kind.
The mass of limestone is not stratified, but suggests deposition in the neigh-
bourhood of a reef through a long period of time. Some coral and numerous
shell casts are to be seen. The greater part of the rock has been redeposited
from solution, is nearly pure calcitc and very hard, often with channels and
openings in different parts of the quarry, in which there are clear evidences of
the action of underground water. The same is to a great extent true of the
o-reat West End quarry, but not of the rocks at the entrance to the town, which
are very little altered, are clearly stratified, and contain well-preserved corals,
small fragments of molluscous shells and sea-egg spines. The limestone rocks
of the west end of the island present, indeed, a difficult, and therefore attrac-
tive, subject of study.

Irregularities.

The reader who fallows up by actual observations the study of the arrange-
ment of the limestone rocks described in the preceding pages, will find
occasional irregularities that have not been hitherto mentioned. The princi-
pal of these known to the present writer is in the neighbourhood of Sion Hill
and on the road from that estate to Sion Farm. Here in the road-cuttings
it is sometimes seen that the marl-beds are about horizontal and occasionally
dip slightlv to the southeast. This peculiarity appears, however, to be merely
local ; for it does not seem possible to trace it through the formation either
towards the north or towards the south, all the dips observed in those parts
being to southwest or thereabouts.

Another irregularity, which in this island appears to be of little conse-
quence as affecting the arrangement of the rocks on a large scale, is neverthe-

30

THE BUILDING OF AN ISLAND.

less very interesting and will not escape an observer's attention. It is the
occurrence of breaks across the strata, breaks which the geologists call faults.
The accompanying sketch, taken from the cliffs at Cane Garden, will show
clearly what is meant bv a fault. It will be seen that the whole mass of the
strata visible in the cliff has been broken across, and that in each of the three
faults shewn, the beds have slidden down a little on one side of the break. Here
the slide is of verv small amount, but faults are known to geologists where
the difference of level in the beds on opjiosite sides is verv great, and among
mountains sometimes amounts even to several thousand feet. In our marl
formation there does not seem to have been much cracking and sliding of the
strata in this way; at all events very few faults show themselves.

The name "fault" is perhaps an unfortunate one, but it is easy to see
how it has arisen, for when the miners in following up a bed of coal or a
mineral vein arc suddenlv stopped by a wall of other beds, not containing the
mineral they are working, they naturally regard the arrangement which gives
them trouble as a fault.

Fic. \%.

riM

70

nP^

^

m

^

^S

Faults in Limestone Rocks ai "Cane Cjauden."

It will be noticed in the sketch, that it is the masses on the upper sides of
the sloping lines of fault which have slidden down. This is the case with the
great majority of faults, and arises from the fact that the rocky mass on the
upper side of the slope has a smaller base, hence less support, and conse-
quently greater tendency to settle down when disturbances of the earth's
crust in their locality take place. It is not difficult, however, to conceive of a
fault being produced during a time of great side pressure while the rocks were
being lifted, and in that case the lighter mass, the mass with the smaller
base, would be pushed upwards, and the common ruU' would be reversed.
Such faults are called "up-thrust" faults. To that class belong many of the
great faults of mountain regions, and examples on a small scale may also be
found in the older formation in our own island.

Thickness of the Limestone Formation.

An enthusiastic observer will no doubt find many other points of interest
in the study of the limestone and marl formation as he proceeds ; here we must
be content with only one more enquiry, namely, what is the greatest thickness
of the formation as it now exists? This (juestion mav be answered approxi-

THE BUILDING OF AN ISLAND. 3 1

mately when we notice that on the Princess Plain the strata come out in
advance of the hills which here border the Central Slope, and dip away under
them in a southeasterly or southwesterly direction, while the hills themselves
reach heights of 400 to 500 feet (at one point 600 feet). Hence a thickness of
at least 600 feet would not be too much to allow for these deposits, an estimate
which we shall scarcely consider as too great when we remember that the
moderate length of cliff at Cane Garden shows, as ascertained by measure-
ment, a thickness of over 200 feet of strata.

Beach and Reef Limestones.

We have now studied the limestone formation in the hills, valleys and
plains that have been carved out of it, but there still remains a class of lime-
stone rocks which, though much younger than those we have been studying,
indeed quite recent, arc of very great interest, because in them we see, as it
were, the sand of the sea being converted into rock before our eyes. In va-
rious places along our sandy shores we find hard, solid beds of rock, which on
being broken into show themselves to be nothing else than grains of sand
firmly bound together. They are, in fact, made from the shore sand. When
these beds are out of the water or exposed at low tide we may conceive that
the binding material has been dissolved from the sand itself bv rain-water con-
taining carbonic acid gas in solution and has been deposited again amongst the
sand grains when the rain-water was afterwards evaporated ; but we find sim-
ilar rocks on the reefs, where they are always under water. There is, there-
fore, some other source of the carbonic acid than the rain-water, and this is
probably to be found in the carbonaceous matter of the animals and seaweeds
that are buried in the sand. At the reef at Christiansted the rock is some-
times broken off in large pieces with crowbars and brought ashore to be used
for building purposes ; hence, blocks of this rock may be seen here and there
in walls in different parts of the town, and they show particles of shells or sea-
weeds, according to the character of the sand from which they were formed.
For the most part they appear to be quite as durable as the stones from the
quarries. Sometimes fragments of such rocks from the reef, on being broken
through and examined with a lens, show the sections of the sand-grains sur-
rounded by a white ring of carbonate of lime, and the same enclosing case is
seen around the small pebbles from the Blue-beach formation which are oc-
casionally found mixed with the shell sand. At Frederiksted this recent lime-
stone rock is not only found along the shore, but in the flat part of the town,
w^here it extends itself inland eastwards, so that several streets are built upon
it. Here the recent date of the rocks may be determined, not onlv bv the fact
that some of the shell fragments have retained their original colours, but also
by the presence of a particular foraminiferous shell that is abundant in our sea
sands at the present time. (See Fig. 11 on Plate B.) Though so recent a
rock, it has already been acted upon bv the weather so far as to be converted
near the surface of the ground into a white mass, in which the sand-grains be-

32 THE Bl'ILDTNCl OV AN ISLAND.

gin to disappear and which breaks loose in an irregular manner from tiie re-
mainder of the rock below. In other words, it is converted, just as in the
older limestones, into a white marl.

Summary.

With the study of the above described very recent rocks we have com-
pleted our general survey of the limestones and marls of the island, and may
now pause to summarize the results of our studies before proceeding to give
attention to the older or " Blue-beach" formation, on which all the rocks of the
later period rest. We have learned, then :

I. — That the limestone formation covers the central, south-central and
southwestern parts of our island.

2. — That the rocks are arranged in strata piled over each other to a great
thickness.

3. — That the whole mass has been formed in the sea by the gradual accu-
mulation of animal and vegetable remains composed mostly of carbonate of
lime which the living creatures have extracted from the sea-water.

4. — That at different times during the deposition of the Hmestones and
marls, considerable quantities of pebbles and finer debris from the older or
"Blue-beach" formation have been washed into the sea and mingled with the
accumulations which the sea-creatures have furnished ; from which it may be
inferred that land of the older formation was not far off during the deposition
of the younger formation.

5. — That great changes in the condition of the rocks have taken place
since thev were deposited, the carbonate of lime having in many cases been
dissolved and, in part at least, re-deposited in other forms, a change which ac-
counts for the hardness of some of the beds, and for the formation of concre-
tions, and which has extended also to many of the fossils deposited with the
rocks. Another important change is shown by the jointing of many of
the beds.

6. — That the whole mass has been raised from the sea-bottom to some
height above the sea-level (certainly 600 ft., and in the first instance probably
much more).

7. — That the slopes or dips of the rocks show that the elevation has been
mostly from the north, but that the dips are also affected by lines of elevation
and (if depression which lie in two directions, namcJv from about northeast to
southwest, and from about noithwest to southeast.

8. — That as a leading result of these movements tlie central part of the
island forms a depression or sort of cross valley filled in with the marl formation,
the removal of which from it would leave a sea-channel across the island from
north to south, making of the Eastern Triangle and the Northwestern Hills
two separate islands. We must remember, however, that this depressed portion

THE BUILDING OF AN ISLAND. 33

was level or nearly level when the deposits were made, so that these may have
extended, and probably did extend, far bevond their present boundaries.

9. — That the rocks have in many places been greatly altered near the
surface of the ground by the weather, sometimes to such an extent that the
original stratification has been effaced and a false stratification, resulting: from
expansion and contraction in alternating wet and dry times, has taken its place.

10. — Lastly, we have seen in the varied surface of hill and dale a proof
that the mass of strata has not remained in the form in which it was lifted
from the sea, but has by some means been sculptured into the existing beauti-
ful undulations. The study of this interesting subject is, however, best left
over till after we have examined the rocks of the older formation, which, even
to a far greater extent than the younger rocks, have been subject to the
sculpturing processes.

34 THE BUILDING OF AN ISLAND.

CHAPTER IV.

TiiK "Blue-beach" or Indurated Clav Formation.

As already mentioned, the " Blue-beach" formation is found throughout
the Eastern Triangle and the hills of the Western Oblong; in fact it occupies
all parts of the island not occupied by the limestone and marl group. Not
only so, but it passes under those rocks, and is the base on which they all rest.
It is therefore the principal, as well as the older formation.

In comparing, at the beginning of our studies, the rocks of the two groups,
it was pointed out that by the simple experiment of dropping a fragment of
each into water containing a little nitric or muriatic acid it can be seen at once
that there is some great difference in their composition, for while the frag-
ment from the younger group effervesces and at last almost disappears, the
fragment from the older group is scarcely, if at all, affected. For a proper
account of their composition, however, we must look to the chemists, and
they tell us that these older rocks are mainly composed of alumina and silica,
the substances which in combination form clay, silica by itself forming flint,
quartz and similar substances.

In 18^9 an American geologist, Prof. S. Hovev, published some observa-
tions on the geology of St. Croix. He distinguishes the two formations of
the island, and calls the older one the Clay Formation. He also mentions it
as indurated clay, a better name, since the rocks, though like clay in their com-
position, have been made intensely hard by processes to which they have been
subjected since they were deposited. He speaks of their composition as va-
rious, in some cases silica, in others alumina, predominating. He also states
that some of the strata near Mt. Victory resemble slates.

In 1868 a Swedish geologist. Prof. P. T. Cleve, visited the northeastern
West Indian Islands and gave an account of their geology. In describing the
ofeoloarv of the Danish Islands he restricts the local name " blue-beach " to a
conglomerate which is abundant in St. Thomas, and he speaks of some of our
Santa Cruz rocks as resembling the said "blue-beach conglomerate." Locally,
however, the term "blue-beach" is applied to all the hard crystalline rocks of
a blue or green colour, and the term "rotten-stone" to the same rock when
broken up by weathering, as we see it in the so-called gravel-pits. Prof.
Cleve also speaks of clay-slate as abundant east of Christiansted and northeast
of Frederiksted, and gives many other interesting particulars, to some of which
we may refer later.

The amateur study of the older rocks is at first rather discouraging, for
they often show no sign of any arrangement, but look like mere masses of
rusty material, presenting no hint as to how their study is to be undertaken.
We find out, however, as we go on, that they give in many places clear in-
dications of regular stratification. In many of them these indications consist
merely of ribbon-like markings on their outer surface, but sometimes the lavers
are also divided along surfaces corresponding to those markings, so as to leave
no possible doubt of their stratified arrangement.

Rocks Showing Stratii'ication Marks, Contentment Road, Near Christiansted.

THE BUILDINC. OF AN ISLANIl. 35

Tlir materials of which these rocks are composed have not, like those of
the limestone rocks, been extracted from the sea-water, but have been washed
down from the land into the sea. If we notice what happens in the harbour
at Christiansted after heavy rains we shall understand how thin layers of such
deposits mav be laid down. The streams after such rains come down from the
hillslopes laden with mud and sand, which settle alona: the shore and for
some distance out in the harbour, each intlux producing a thin addition to the
deposits. Further light is thrown on the subject by the experience of Martin-
ique and St. Vincent after the volcanic eruptions of 1902, when vast quantities
of the dust and stones thrown out by the volcanoes were washed down into
the sea. As we proceed we shall find some reason to suppose it likely that
the older rocks of our Danish Islands, and perhaps the whole chain to which
they belong, may have originated from volcanic action, but we must not be too
sure of that ; what is quite certain, however, is that these rocks have been
formed bv debris brouafht down from the land antl arranged in strata in the
sea bottom.

After having found that the rocks we are now studying are, at all events to
a great extent, stratified, it strikes us as very strange when we discover that they
are at the same time crystalli7ic, for the materials of which they are composed
are not, like carbonate of lime, easily dissolved in water and redeposited in a
crystallized state; but it is known that such materials require also a high degree
of heat to change their form. It appears, then, that these rocks have
been subjected to high temperatures, since their deposition as mud and sand
in the ancient seas, and by such high temperatures and the presence of water at
the same time, have been so far altered that their stratification for the most part
has disappeared, to make itself evident, however, when the weather acts on the
exposed surfaces and reveals the stratification anew. In some cases, how-
ever, the changes seem to have gone so far that the mass shows no sign
whatever of stratification, but resembles those rocks that are found in many
parts of the world with forms so plainly showing the action of heat that they
are known as ''igneous rocks."

We do, indeed, find here and there in the older formation of this island
some masses of rock that evidently have been forced up from below and are
genuine igneous rocks ; but these cases are few. The great mass has
undoubtedly been first deposited in sedimentary layers and has afterwards been
changed by heat. The name igneo-sedimentary has sometimes been given
to such rocks. In a few of the strata the change to the crystalline form has
not been carried very far, and these are of great interest, because the records
of the past are best preserved in them, as we shall shortly see.

Having convinced ourselves that the rocks of the ■• Blue-beach" or day
formation, in spite of iheir crystallization, are in reality stratified rocks, we may
next proceed to study the facts connected with the strata, and the first thing
that strikes us is the high angle to which they have been forced up; so that,
while the limestone rocks of the younger formation dip at low angles of 10 to
15 degrees, the older rocks commonly reach at least 45 degrees. On the

36 THE BUII-DING OF AN ISLAND.

eastern and western borders of the town of Christiansted, at Judith's Fancy
and at many other places, such a dip may be observ^ed. High dips are, in fact,
general, in whatever direction the rocks may slope. Although occasionally less
than 45 degrees, it is in some places much greater ; near West End, for ex-
ample, where the road past " Wheel of Fortune " runs over the upturned edges
of these rocks, the dip reaches as high as 70 or 80; at " Waiter's Point," south
of Christiansted, on the southern shore, some of the layers are absolutely iip-
rio/d ; while along the south shore of " Buck Island " the tilting of the strata
has been carried further still, so that some of the layers, which at one place are
vertical, are, at a short distance farther on along the shore, carried so far over
that they actually pass the upright and so come to dip in the opposite direc-
tion, showing what the geologists call a "reversed dip."

Relative Positions of the Two Formations.

There is no spot known to the present writer where the limestone forma-
tion mav be seen in actual contact with the rocks of the older formation.
While, however, there does not appear to be any exhibition of the actual con-
tact of the two formations, there are many places where the relative positions
of the two sets of rocks are plain enough. For example, on the Bulow's
Minde hill, where the limestone which caps the hill is succeeded lower down by
"blue-beach" rocks, as shown in "gravel pits" and by the gravelly character
of the soil. The same is seen at a point further south — namely, on the hill
near Granard, where the brow of the hill looking east shows limestone beds,
while lower down these are succeeded by gravelly soil derived from the older
formation. Again at West End (Frederiksted) the limestone formation extends
eastwards to include the small hill back of the town, and then gives way to the
gravelly deposits derived from and extending towards the "blue-beach" hills.
The neighbourhood of West End presents, indeed, a most interesting exhibi-
tion of the relations between the two sets of rocks. It has already been men-
tioned that the layers of the older rocks have been lifted to very high angles
(70 or 80 degrees), and thev may be seen in a gravel pit and in the road
trenches from near Concordia to near Wheel of Fortune. They dip at the
steep angles named towards south by east, and the roadway runs on the up-
turned edges, as shown in the diagram (Fig. 14). These layers are very dis-
tinct as seen in the trenches, and are sometimes shown on the roadway itself
in a very interesting manner; the differences in the composition of the various
layers have given rise to differences in the rates of their decomposition, so that
it has gone deeper into the edges of some of the strata than into the edges of
others; hence, some of these edges retain water better than others, and when
the road is drying after rain these more absorbent strata arc indicated by damp
bands across the roadway. For the same reason vegetation is sometimes seen
to be more vigorous along some edges than along others, and in this way a
field of guinea-grass east of the town of Frederiksted not infrequently shows
the direction of the edges of the strata by alternating bands of a darker and a

Stratified Rocks on the Shore West of Fort Augusta, Near Christiansted Harbour.

THE KUII.DING OF AN ISLAND.

2>7

lighter green. Even the coarser vegetation shows in one place a like result —
namely, on the south side of the northwestern block of hills, where on the
side of one of the hill-spurs the direction of the stratification may be recog-
nized from a distance of a couple of miles to the eastward by the parallel lines
of flourishing bush vegetation passing down the hillside.

Fig.

14.

Jr.

IXO-OLOU \)U/f^a.'L£^

s.

High Dip along West Fnd Koah.

The dip to the south, above considered, extends over an extensive area, as
•we shall presently see, and it is on the upturned edges of these highlv inclined
strata that the moderatelv sloping limestones at West End rest. In geological
language the limestone rocks here are said to rest unconformably on the Blue-
beach, and the same is undoubtedly the case in all other parts of the island
where the limestone formation is found. Let us, however, leave this question
for the present and return to the study of the early history of the older rocks —
that is to say, the history of their making. While it is certain from the fact of
their stratification that these rocks were deposited in water, and almost certain
that the water was that of the sea, yet it appears at first sight that we can get
no other evidence on this point, the general absence of fossils giving us the
idea that the sea surrounding the land of that day was so disturbed bv the con-
tinual influx of detritus, volcanic ashes and debris perhaps, from the shore, that
the sea creatures had no chance to contribute even an occasional bed of lime-
stone to confirm the hint which the mere fact of their stratification affords,
that the rocks were built up in the sea. And" this idea of the prevailing con-
ditions, with certain limitations, is probably in the main correct ; vet as we
continue our observation of the rocks, we find, contrarv to our first impressions,
that there are after all a few remains of limestone beds, and that these present
clear evidence of their origin in the sea. One of these beds of limestone is
found in a little hill near the shore on the estate St. John's and near to Judith's
Fancy. Professor Cleve thus writes of it : " Greyish compact limestone is
found, as far as I know, only in one spot, near Judith's Fancy. The rock is
hard, dark grey and fine-grained. It contains a great number of badly pre-
served fossils, so altered that I have not been able to find out of what kind
they are." He also mentions a band of greyish limestone in Buck Island; a
band which is not known to the present writer. It does not seem, however
that the Professor's attention was called to the rocks at Waiter's Point, a head-
land on the southern shore nearly south of Christiansted, where the strata are
particularly interesting.

;8

THE 15LIILDING OF AN ISLAND.

On the east side of Waiter's Point the rocks are very similar to those
common around Christiansted, externally brown and plainly stratified, but
without fossils, the strata dipping at about 45 degrees to the southwest ; but
when we pass to the western side of the point we find a set of strata of varied
character and standing at very high angles, some of them absolutely vertical.
A fossil sea-egg. for example, has been found here on the surface of a bed of
gritty rock now quite upright, which, when the sea-egg lived on its surface
and was embedded in the sand, was certainly level or nearly so.

The strata here consist of limestones, indurated clays, etc., and at one
place there is a rather extensive intrusion of igneous rock from below. Some
of the limestones are compact, but others seem to be made up of broken frag-
ments cemented together, and at least one bed of gritty rock seems to contain
waterworn fragments of the same limestone. In the limestone layers, numerous
specimens of a very curious fossil are embedded. In outward appearance and
in the cross-section these so much resemble plant stems of some kind that the
present writer has hitherto regarded them as such, but, on submitting some of
them to scientific examination in New York recentlv, has been informed that
the apparent stem fragments are of animal origin, showing "coralline or some
similar animal structure." One of the best specimens collected is several
inches in length and about seven inches across. It has in one part a black
outer covering, suggesting the bark of a stem, while running up through it
and parallel to each other there are black columns that look like the bundles
of fibres that run through the stems of some plants. The arrangement is
shown in the accompanying sketch of a small fragment (Fig. 15). In the
above mentioned larger specimen, there are fifty-four of the radiating lines of
black spots, such as those shown in the diagram. Presumably the creature,
parts of whose form we find preserved in these fossils, was a gigantic animal-
flower (sea-anemone), from which the spreading arms of the top have disap-
peared. Possibly the lower or stem-like portion of the creature was strength-
ened by a considerable deposit of lime in part of the flesh ; for it seems difficult.

Fi<;. I s-

THE BUH.DINO OF AN ISLAND. 39

otherwise, to see how the form could have been so well retained as we actually
find it In any case, we have here a fossil of great interest and that may
possibly be of some value to geologists in helping to find the relation of our
St. Croix strata to those of other parts of the world.

Fossil fragments similar to those described above are to be found in the
cliffs near to the ancient limestone rock at the estate St. John's, and also at
the estate Salt River, where they may be seen in some thin beds that cross
the main road. Besides the fossil remains above mentioned, the limestones at
all the places named contain foraminiferous shells, the section showing a
coiled shell with numerous chambers. .

Conglomerates.

Leaving the subject of the fossils, we may now turn to another interesting
question, namely, the occurrence of conglomerates in the blue-beach formation.
Prof. Hovey, in his notes alreatly referred to, remarks in reference to these
rocks " no conglomerates," and this must certainly have been correct for the
rocks he examined. The present writer, indeed, has not noticed any conglom-
erates among the rocks of the northwest, which appears to have been the part
examined by the professor; but has seen them in other parts of the island.
At the west end of Buck Island there is a bed of true conglomerate ('• pud-
ding-stone "), that is to say, the pebbles are all thoroughly water-worn. In
other places may be seen conglomerates in which the embedded fragments
retain entirely or in a great degree their angular form, the stone belonging
more nearly, therefore, to what the Italian geologists called "breccia." De-
tached blocks of rock of this sort may be seen at Hermon Hill ; while at Salt
River Point there is a great mass of rock of similar character. The same is
true of the point projecting northward in the middle of the Salt River. At
Hermon Hill the blocks have evidently been broken off from a thick layer,
which, however, the present writer has not been able to locate ; but at the
two points mentioned no stratification can be made out, and the appearance of
the rock suggests that it has been a mass of debris, such as we now see spread
over our Central Plain, and has been subsequently hardened. Professor Cleve,
speaking of the St. Thomas rocks, says: "the occurrence of scoriaceous (cin-
dery) pieces in the conglomerate indicates its volcanic origin." Though not
seen by the present writer, it is not unlikelv that conglomerates of similar
character exist also in St. Croix.

Travertine.

Reviewing what we have so far learned in regard to the origin of the older
rocks of our island, we may say that we have seen that thev were formed from
debris of greater or less fineness, and most likely of ultimate volcanic origin,
brought down from an adjacent land by streams into the sea, formi-ng there
mud deposits and conglomerates arranged in definite layers, subsequently to be
altered to the hard rocks, which Professor Hovey describes as indurated clay, and

40 THE BlilLPTXC OF AN ISLAND.

further that the sea, at one time durinij the long period of the piling up of the
clay rocks, not only received and arranged all this material, but also furnished
its own quota in the shape of a few limestone beds, which in some parts, as in
the limestones at St. John's estate, are so nearly pure as to contain over 90 per
cent, of carbonate of lime; in other parts, as at Waiter's Point, mostly impure,
but containing numerous fossils of considerable interest.

The presence here and there of limestone beds in the blue-beach forma-
tion, taken together with the power of carbonic acid to dissolve carbonate of
lime, suggests to us that after all there mav have been other, even though less
abundant, deposits of lime elsewhere throughout the formation, deposits which
have disappeared under the dissolving process. In that case we should be in
error if we inferred from the absence of such beds an absence of sea-life during
the period or its powerlessness to leave anv record. And this view of the
matter is strengthened by the fact that some of the older rocks do contain a
fair amount of lime in their composition. In the northwestern hills the
presence of lime in the rock is shown in a most interesting way. On the road
up the hill from " Little La Grange " to " Punch " an old watercourse is cut
through, in which some exceedingly curious deposits of limestone may be seen.
The limestone is in masses having rounded tops, and when carefully examined
is found to be light and porous, to be made up, in fact, of small cells, some-
what irregularly arranged in thin layers, one over the other. The rock also
contains impressions of stems and leaves. The origin of this singular rock,
which is called ''Travcrtiney maybe seen in the neighbouring stream that
passes down the beautiful vallev known as Crequi's. There some of the larger
blue-beach rocks in the bed of this stream may be seen to have acquired a
similar rounded form, the covering being a substance composed of like
material, and if examined while the water runs over them, thev will be found
to be covered with a slimv vegetable growth, a growth which doubtlessly
absorbs the lime brought out of the rocks bv fresh water, and on the subsidence
of the water dies, leaving a limestone crust. Such crusts deposited one over
the other, through a long period, make the blocks such as we see in the above-
mentioned old stream-bed. No similar growth of Travertine has been found
by the present writer in the other streams of the island ; but in the watercourse
which passes out into the plain near Grove Place, lie has found among the
pebbles a water-worn fragment of this curious rock, proving its existence
higher up in the stream's course. While, therefore, the great preponderance
of the clay class of rocks in the blue-beach formation is obvious, we have to
modifv our conclusions so far as to admit that the lime deposits may have been
originallv more numerous than now appears.

Although we have thus come to a conception of the origin of our older
rocks, which is probablv near the truth, there remain many interesting points
in regard to thein yet to be studied.

The crvstallization of many of the rocks, which obliterates the stratification,
and the weathering whicii so often reveals it again, havi' alreadv been men-

THE BUILDING OF AN ISLAND. 4 1

tioned. Another curious change in the rock has been the development in it,
in some places, of numerous small bodies resembling peas in shape, and gen-
erally in size also, though sometimes much smaller. This singular result is
shown abundantly in the rocks in Christiansted and the neighbourhood; but
mav also be seen in many other places. It has arisen from the tendency of
some component of the rock to get together into small masses; it is, in fact,
a sort of imperfect crystallization and is technically known as concretion.
When the rock is acted on by the weather, the little balls stand out on the
surface of the stone, in other cases they have been cut through where natural
splits in the rock have occurred, and then they are represented on the surface
by small round patches, generally of a lighter colour than the rest of the
stone.

A quarry near the roadside east of Christiansted presents some evidence as
to the way in which the process went on. We see on some of the rock faces
there very thin bands of paler colour than the rest of the surface, the edges,
in fact, of thin layers. In some cases we see these bands broken into short
lengths, as if the material which gave the lighter colour had been drawing
together in patches; while in other cases again the process has been com-
pleted, the material has been collected in little balls all along the line. In
the majority of instances, however, the structure in question has arisen in
much thicker beds, and then there is frequently very little regularity in its
development.

The structure above described is called by geologists variolitic, a word
which refers merely to the variation produced in the stone by the concretionary
process. Its occurrence in the rocks is often of great assistance in the deter-
mination of the dip. In availing ourselves of its aid for this purpose it is ne-
cessary, however, to use a little caution ; for it sometimes happens that the
structure tends to follow the Joints of the rock, and if we are not aware of this
fact we may be misled into taking the direction of the jointing planes for the
direction of the stratification. Generally, however, a careful study of the case
will save us from this error.

In connection with this variolitic structure, another effect of a somewhat
similar nature may be noted. A few layers of the older formation may be
found in which the tendency of some constituent of the rock to collect towards
definite points is shown in a very curious result, namely, in converting the
whole bed of rock intt) a number of rounded bodies composed of successive
layers, which, under the action of the weather, peel off like the coats of an
onion. These rounded bodies are all close together, so that the rock is quite
solid, but where the weather acts on it they show themselves, and the coats
commence to break away. Such a layer of rock with concretionary forms of
this sort, most of them three or four inches across, may be seen in the bed of
the stream which passes under the new bridge south of Cornhill.

Another interesting fact is the splitting of the indurated rock in various
directions, so that the fragments generally present several straight sides, the

42 THE DUILDINC OK A.N ISLAND.

faces being flat. The planes of divisions are technically called "joints." The
tendency to split in this way is very common, and generally becomes con-
spicuous when the rock is acted on by the weather ; in some cases, however,
the rock is solid and very hard, and onlv comes awav in large blocks. Some-
times the jointing is so regular in parallel planes in a given direction that we
have to be on our guard not to mistake it for stratification.

Perhaps the most remarkable change of all, a change allied, may be, in its
nature to that mentioned above, is that which has taken place in the slate
rocks. Essentially these rocks resemble in composition the other rocks of the
older formation, but the texture is very fine, and thev have underafone a
process which has originated a structure called cleavage. Cleavage is a
peculiar property that distinguishes slates from all other clay rocks. It is the
tendency to split along parallel surfaces into slabs of varying thickness according
to the (]ualitv of the rock. These cleavage surfaces or planes do not follow
the planes of stratification but are often placed at a considerable angle to them.
They are, in fact, quite independent of the way in which the material has been
put down, and have arisen from the enormous pressure to which that material
has been subjected later. In the well-examined slate districts of European
countries and North America, it has been shown that the direction of the
cleavage depends on the direction of the neighbouring axis of elevation; it
follows in a general way the direction of that axis, from which it may be in-
ferred that the pressure which has forced up the wave of the earth's crust,
known as an anticlinal, has also pressed on the clay rocks with such intensity
that they have rearranged their particles in the form of adjacent plates. The
fact that pressure has caused this rearrangement cannot, so far as the present
writer knows, be shown in the St. Croix slates, but in other lands, where fossil
shells arc sometimes found embedded in the slate, it is seen that the shells are
lengthened in tiie direction of the cleavage and shortened in the cross direction ;
they have, in other words, been squeezed out of shape and always in the way
described. What is thus proved for many slate formations mav be assumed
as true of ours. Professor Cleve, writing of the clay-slate of St. Croix, savs
that "it is perfectly cleavable," that is to say, he found that he could split il
along the cleavage planes in the same way as the European or American slates
are split ; but this must not be taken to mean that they have any commercial
value ; the beds are neither thick enough nor fine enough for that. The
cleavage is also most generally irregular, as far as the present writer has been
able to ascertain, and the slates are frequently in thin beds, and these are often
interstratified with other rocks, which show the cleavage in a less distinct wav.

It may also be noted that the planes of cleavage in the slates are some-
times shown by fine white lines along the surfaces of splits in the rock; and
the edges of the thin slabs occasionally appear as tiny parallel waves. Thus it
will be seen that the cleavage is a very interesting feature of the slate rocks,
and leaves room for extensive study, equally with other changes of which
evidence has been observed, such as the crystallization, the formation of con-
cretions and the jointing.

THE BUILDING OF AN ISLAND. 43

So far our observations of the older rocks have tausfht us somethinaf of
their origin, and something of the remarkable changes which they have under-
ofone since thev were laid down in the sea, and amona: these changes we have
noted that in the process of their elevation they have been forced up into
highly sloping positions, and we have also observed in a general way that the
slopes or dips are not all in the same direction. So varied are they, in fact,
that our first observations in different parts of the island would almost lead us
to despair of ever finding any system in the arrangement of these ancient
strata ; but if we go on collecting and mapping our information, order begins,
by-and-bv, to appear out of chaos, and the subject becomes one of absorbing
interest.

44

THE BUlLUlNf; OF AN' ISLAND.

CHAPTER V.

Arrangement of the "Blue-beach" Rocks.

After having accumulated a good many observations in regard to the dip
of the blue-beach set of rocks, one of the first things we discover is that the
varied dips admit of being grouped into two great classes, namely, in the first
place, the dips which look to some point in the southern quadrant — that is to
say, they are all included between southeast and southwest, and, in the second
place, the dips which look to some point in the northeast quadrant — that is to
say, thev are all included between north and east. The accompanying diagram
makes this distinction clear at a glance. The dips of the blue-beach rocks but
very rarely pass beyond the limits here indicated for each class, and in continu-
ing our studies vve soon discover the great value of this classification. We
soon find that one or other of these two sets of dips extends itself continuously
over a considerable section of the island and becomes characteristic of that
section, while by-and-by we are furthermore able to make out the boundaries
between the various sections, and finally reach definite and most instructive
conclusions.

Fk;. i6.

Arrangement of the Rocks in the Western Oblong.

In commencing our observations for ascertaining the arrangement of the
rocks of the blue-beach formation it is most convenient to begin with the
Western Oblong, where the points above mentioned are illustrated in a clear
way and on a large scale. The highly inclined strata whose edges cross the
high-road to Frederiksted, and may be seen for a considerable part of the way
between the works at Lower Concordia and those at Wheel of Fortune, have
already been mentioned, and it was also pointed out in what an interesting wav
the presence of these strata is revealed, even where their edges are covered by
road material or by soil and vegetation.

THE IJUILDING OF AN ISLAND. 45

The special dip of the rocks seen along the piece of road above named —
that is to sa}', a dip to south or south by east, can be shown to extend over a
large part of the northwestern hills, but we soon find that it bv no means extends
over all pairts of them ; to the north and east another dip prevails, namely, a
dip to east-northeast or points near to that. These latter dips are as prevalent
over the northeastern half of the hill-block as southerly dips are prevalent over
their southwestern half. It is, moreover, possible, by making suftlcientlv nu-
merous observations, to ascertain approximately where the line lies that sepa-
rates the two areas of different dips, and to show that it passes through the
hills from about west-northwest to east-southeast, as shown on the accompa-
nying sketch map.*

The discovery of the dividing line between these two areas of differing
dips is sufficient to show that there is an order of some sort in the arrange-
ment of the strata; but it remains to find out how that order is to be inter-
preted. What has happened to bring about such an arrangement of these
rocks ?

Upturned edges are found everywhere throughout both areas, but are
most striking in the southern area, along the road near Concordia, already
mentioned, where the abruptness of the edges is so conspicuous that we natu-
rally ask what has become of the parts that must have been removed to show
these remarkable edges ?

It is not difficult to see that, given time enough, the wearing away of a
large portion of the strata could be accounted for by the action of rains and
the consequent rills and streams passing over the rockv edges, a destruction
which, in fact, may be observed to be going on at the present day; but what
forms had the strata in earlier times ? Were they by gigantic forces broken
off somewhat above the present edges, and if so, what forces broke them off,
and what has become of the upper part so broken off ? Or did thev fold over,
as their direction seems to hint, towards the north, the top or arch of the fold,
in that case, having since been worn away? And if the rocks have been
folded over, how can the southerly-dipping rocks be connected by a fold with
the more northern rocks, which have a dip almost at right angles to theirs ?

Had the two dips, as in the diagram (Fig. i8), been at right angles to the
line of division which we have been able to lav down between the two areas,
the explanation would have been very simple ; the line in question would give
the position of an anticlinal axis, from which the rocks slope awa)' on each
side, and it would only remain to explain the removal of the vast mass of rocks
forming the upper part of the anticlinal curve.

In such case the whole storv would be shown in a diagram such as that
given below (Fig. 19), which represents a cross-section, lying about north-
northeast and south-southwest.

* The reader who wishes to follow up this investigation in detail will find it dealt with in the Notes
■which follow these Chapters.

46

THE BUILDING OF AN JSLAND.

REFERENCE TABLE.

H. B.— Ham's Bay.

N. S.— North Side.

S. G. — Sprins; Garden.

M. v.— Mt. Victory.

A. — Annaly.

P.— Punch.

S. H.— Sprat Hall.

B. B.— Butler's Bay.
O.— O.xford.

O. G. — Oransje Grove.
W.— Williams.
J. H.— Jolly Hill.
P. — Prosperity.
La G. — La Grange.

C. v.— Cane Vallev.

W. F,— Wheel of Fortune.

C. — Concordia (Lower).

T. W.— Two Williams.

St. G. H.— St. George's Hill.

H . — H I igensborg.

S. G.— Stony Ground.

H. R.— Hannah's Rest.

W. B. — White's Bay.

Wh.— Whim.

G. H.—Good Hope.

Ca. — Carlton.

P. — Prosperity (North).

N. S.— North Star.

C. B.— Cane Bay.

La v.— La Vallee.

M. S.— Mt. Stewart.

F. — Fountain.

Mt. E. R.— Mt. Eagle Ridge.

M. — Montpellier.

T. F.— Two Friends.

H. — Hermitage.

M. P.— Mt. Pleasant i^Colquohoun),

B. G.— Beck's Grove.
A.— AUandale.

G. P.— Grove Place.

U. L. — Upper Love.

J. — Jealousy.

M. — Mountain.

St. G.— St. George's.

P. — Plessens.

Mt. P.— Mt. Pleasant.

L. L. — Lower Love.

C. B.— Castle Bourke.

D. S. — Diamond School.
D. — Diamond.

P. — Paradise.

A. ^Adventure.

E. G.— Enfield Green.

B. H. — Betty's Hope.

C. B. — Cooper's Bay.
E. — Envy.

Fig. 19.

^txnxl:.

^\V^^ ..

S. S. — Sea level.

S. D. — Southwestern dipping --trata.

N. IC. D. — Northeastern dipping strata.

D. S. — Position of strata, assumed to have been ilenudeil.

THE BUILDING OF AN ISLAND.

Fig. I 7.

47

Anticlinal Axis and Svnclinal Axis of the Northwest.

48

THE BUILDING OF AN ISLAND.

But the two sets of strata do not dip away at right angles to the axis but
in a sloping direction on each side (Fig. 20), and we must ask, how is this to
be explained ? For an explanation we may fall back on an earlier result of our
investigations. In our study of the limestone formation we saw that some of
the lines marking the divisions between sets of limestone strata having differ-
ent dips ran across other lines, indicating that the forces of elevation acted in
two directions, crossing each other, though perhaps not exactly at right angles.
We saw, for instance, that the limestones of the great Synclinal of the Central
Slope do not dip at right angles to the axis but come down to it from the
northeast on one side and from the northwest on the other, indicating a cross-
elevation from the north.

Fig. 20.

And, what has a more tlirect bearing on the case before us, we saw in" re-
gard to the anticlinal of the Mt, Eagle Ridge that as we followed the axis
from the ridge across the plain and down the Barren Spot Valley the strata on .
either hand passed away to southeast on the one side and to south-by-west on
the other, not by any means at right angles to the axis, but with a southerly
inclination which could onlv be explained bv supposing that there was also a
tilting from the north. So in the larger case we are now considering, we have
onlv to suppose that besides the pressure from the north-northeast which
pushed up the ancient strata into a great fold (or into folds, as we shall see
later), there has been another force acting from a line of elevation to the west
which has given the sloping direction of the dips on both sides of the anti-
clinal.

When studying the Mt. Eagle anticlinal, the fust which we met with in
our investigations, we found that the case was well represented by an open
book turned down on the table and then tilted from one end. and the same
illustration will serve us in the present case. In fact, it seems that the illus-
tration of the open book, simple as it is, gives the whole story so far as the
directions of the dips over the areas in question are concerned, but it does not

THE BUILDING OF AN ISLAND. 49

illustrate the subsequent levelling down of the strata. The diagram (Fig. 19)
may still be taken as roughly representing the anticlinal, if we remember that
the strata slope partly forwards as well as to right and left ; but the diagram
would require some modification before it could be taken fairly to represent
the facts ; for the high dips, reaching sometimes even to reversions along the
south side of the axis, compared with the more moderate dips along the north
side, suggest that the curve of the elevated strata has not by any means been
an evenly balanced one, but has been far steeper on the south side than on the
north. After making this change there might still remain some subordinate
folds in the strata which would lessen the height of the main curve. Yet it
is evident that in any case it must have been very great. What an immense
time must be allowed for the atmosphere, the rain and the streams to have
worn away such vast masses of strata as this theory of their present arrange-
ment implies ! Even if we suppose these agencies to have had in remote times
a much greater force than they have in modern davs, yet we can onlv imagine
that long ages must have passed during which these old rocks were being eaten
down, to disappear later beneath the surface of the sea and to receive on their
worn down edges the gi'eat deposits of limestone and marls which make up
our newer formation.

But, to return to our observations. Following up the question of the ex-
tent of the northeastern dips, we find that while it extends eastwards, it is
stopped short northwards by southerly dips, which, beginning at " Will's Bay,"
occupy the northern shores as far east as the estate St. John's and are renewed
still further east across the Salt River and in Christiansted.

This change back to a southerly dip presents, however, no further diffi-
culty. In coming to it we have merely arrived at a second great wave of
the strata, and the line, which separates it from the area of northeastern dips
already considered, is the line along the hollow of the wave, a synclinal axis,
just as the former line of separation further south is the line along the top of
the wave or ridge, an anticlinal axis.

Thus we seem to have arrived at a satisfactory explanation of the arrange-
ment of the older rocks in the western part of the island, and with the knowl-
edge we have gained we may now proceed to a similar examination of those of
the Eastern Triano-le.

Beginning with the hills at Christiansted we observe that, with an excep-
tion to be noted later, the dips in the town and near neighbourhood are to
southerly points. If we now take advantage of the great slit through the
Christiansted hills, "Spring Gut," as it is commonly called, and pass through
it from north to south, namely, from the "Parade Ground," east of Christian-
sted, to the estate Longford, we find as we ascend the valley, which at its
highest point is about 400 feet above the sea-level, that, with one exception, a
southerly dip prevails wherever the rocks show signs of stratification, but soon
after we begin to descend on the south side, a striking change occurs, the dip
passes in the space of a few yards 'from about southwest to east-bv-north.

50 THE BUILDING OF AN ISLAND.

There is here, in fact, a fold in the strata. The rocks are hard beds of in-
durated clay, and towards the centre of the fold there are some slaty strata
with a very rough cleavage. The soil and debris of the road-bank hide the
junction of the two dips, but the slaty rocks at the two sides approach near to
each other. Nor is this change in the dip confined to the narrow space here
visible, for we find the layers lower down the hill dipping also E. by N. (at
about 45 degrees), and at Longford, at the foot of the hills, we find in the
road-trenches the rocky layers dipping at a high angle to E.N.E. It appears,
then, that at the spot where the change was noticed, we have passed from a
strip of country with dips within the southern quadrant into a strip of country
with dips within the northeast quadrant. If the rule which we found to
prevail in the Western Oblong can be applied to the Eastern Triangle, then
the boundary between these strips should lie about west-northwest and east-
southeast.

Numerous observations along the shore and on either hand show this to
be the case, and enable us not only to mark down the northern limit of this
strip into which we have come, but also its southern limit. This southern
limit marks it off from the Waiter's Point district, in which we return to
southerly dips.

Thus we have established that the key discovered to the arrangement of
the rocks in the Western Oblong is also the key to the arrangement in the
Eastern Triangle, at all events for its western part ; that is to say, the rocks
bere, as in the northwest, have been forced up into folds by great pressure from
about north-northeast. Bv following the same method of observing and map-
ping out the dips at various points we shall find that the arrangement prevails
throughout the Eastern Triangle. The different anticlinals and synclinals will
be found noted on the map prefixed to these pages, and those readers who wish
to follow out the details of the observations will find them entered in the ap-
pended Notes.

The large folds of the rock layers which have been so far worked out
must be the principal, but considering that we cannot everywhere get access
to the rocks, and considering that we occasionally, though rarelv, meet with ex-
ceptional dips, it may be that other smaller folds occur. Contortions are not
uncommon, and it may well be that there are some small folds also. Fuller
observations of the rocks may discover these and thus make some modifica-
tions of the present results necessary.

Contortions.

Reference has been made above to "contortions" as being "not uncom-
mon " ; at the same time it must be noted that these twists in the strata are
not as frequent as we might suppose when we think of the immense pressure
there must have been on the rocks to force them up into the great ridges and
hollows which we have just studied. Examples of contortions may be seen at
the Fort in Christiansted, at Fort Augusta at the entrance to the harbour, and

THE BUILDING OF AN ISLAND.

51

cl,

in the cliffs beyond Princess, where the writer has X seen bend in the strata re-
sembling a large S. The most curious case met with by the present writer,
however, is to be seen at Ham's Bluff, where some very thin sheets lying close
together in a broader band have been squeezed up into small ripples, the lavers
above and below remaining unaffected. This interesting result is shown in the
diagram (Fig. 21), and mav be explained by supposing that the waved layers

Fi(

2 I.

Small cnntortioiib in rocks at Hams lilull.

began to stiffen, for some reason to be sought in their composition, earlier than
the adjoining material, so that while the latter yielded to the squeeze the for-
mer could only accommodate itself to the reduced space bv falling into folds.
It is doubtless the same necessity which has given rise to all contortions, but
it is seldom that we meet with so compact and clear an illustration of it.

Summary.

To sum up this (luestion of the folding of the " blue-beach " rocks, it will
have been seen that in both the Western Oblong and in the Eastern Triangle
we possess clear evidence that the ancient strata of the island have been pushed
back into folds by some tremendous force acting from about north-northeast,
and that the effects of this force have been modified by a force acting crosswise
to it. We have been able to mark down approximately the positions of the
lines which mark the crests and the hollows of these folds — that is to say, the
folds that hav^ been produced by the force from north-northeast, and in this
way we have come to some idea of how the island's strata are now arranged.
The marvel of the removal of the vast masses of the crest of the folds or
waves so as to show everywhere the edges of the strata, still remains, a marvel
which, after all, is only slightly lessened by our knowledge of the power of the
sea and the rains to plane down the land surfaces.

If we now pause to summarize what we have so far learned about the
older of the two formations of our island, we find :

I. — That it is essentiallv different from the younger group, being substan-
tiallv a clav formation, while the latter is a lime formation ; the one material a

52 THE BUILDING OF AN ISLAND.

product idtiviatcly of igneous rocks, the other extracted from sea-water by
living agencies.

2. — That, although ultimately in the main a product of igneous rocks, it
has been laid down in the sea in regular strata.

3. — That the supply of material has apparently been so abundant and so
continuous as to allow only of a small contemporaneous deposition of lime-
stone by the sea creatures, yet that there are, nevertheless, some scanty re-
mains of such limestone deposits, and that these contain distinct evidences of
their origin in the sea.

4. — That after their deposition in the sea the strata have been greatly
altered by heat and water, so that they have for the most part taken a crys-
talline form.

5. — That they have also undergone some other remarkable changes, such
as attaining in many of the beds the variolitic character, the tendencv to split
in certain directions, known as jointino; and especially in this connection, in so
far as the slaty rocks are concerned, the ac(|uisition of cleavage.

6. — That while these changes were going on, or at all events since the de-
position of the materials, the whole mass of strata was forced up bv pressure,
from about north-northeast, into parallel waves or ridges, whose form has again
been affected by pressure crosswise to the above-named direction.

-. — That the crests of these waves were eaten awav through a vast period
of time by incessant attacks from the sea along the land edges and by the rains
and the consequent streams over the surface, so that at last thev were planed
down, perhaps so far even as to leave an approximately level surface, present-
ins evervwhere the edijcs of the strata.

<S. — That the land so planed down then sank under the sea and received
on the upturned edges of the strata, during another vast period of time, the
deposits which make up our limestone and marl formation.

9. — That having received these large deposits on the upturned edges of
the strata, the whole mass was once more forced up, bringing them above the
surface of the water along with it.

10. — That both formations have since then, and partly also during the lift-
ing ])rocess, l)een acted on bv the sea and by the rains and streams, so as to
have their surfaces carved into the forms we now see, a subject, however,
which' has so large a scope that it will be well to reserve it for separate study.

Before proceeding to that subject we mav take a brief look at the igneous
rocks which have been intruded from below into the older formation but have
never, so far as is known to the present writer, reached so high or been in-
truded so late as to show themselves in the newer or limestone formation.

THE BUILDING OF AN ISLAND. 53

CHAPTER VI.

The Igneous Rocks.

Our examination of the stratified rocks of the Clay Formation has shown
us that a large proportion of them are crystalline, and that the change has been
in many instances carried so far that the marks of stratification are not brought
out by weathering, and in these cases it is only the gradual passage of the rock
from the stratified form to the unstratified form which convinces us that the
latter is in reality a sedimentary rock like the former, only that it has under-
gone a higher degree of alteration.

Occasionally, however, we meet with some form of crystalline rock which
has plainly been thrust through the stratified rocks, and it is in this case evident
that the former has been in a molten condition when it was thus forced
through the strata.

The igneous rocks thus forced through the strata are frequentlv met with
in the form of walls of greater or less width, technically known as "dykes."
Such dykes are to be seen here and there in our older formation. The most
accessible example from Christiansted is a dyke in the quarry immediately east
of the town on the south side of the high-road. The stratification of the rocks
in this quarry is very plainly marked. They dip at about 45 degrees to the south,
and the dyke cuts them through in a wall about 6 to 8 feet thick. Its length
lies northwest and southeast, and it slopes at about 60 degrees to southwest.
The rock in this dyke is slaty blue or grey in colour, is speckled with distinct
crystals and is very hard. Another good example may be seen at Fort Au-
gusta, at the entrance to Christiansted harbour. The stratified rocks at the
Point are in dark slate-coloured and brown layers alternately, all much con-
torted, but mainly dipping at an angle of about 30 degrees to south. Through
these rocks a broad dyke passes across the Point north and south showing
itself in the clifl^s on both sides. In the yard of the Fort, which at the present
writing is bare of gravel, the rock of the dyke may be very plainly seen in con-
tact with the beds of the stratified rock, which it has bent backwards, so that
they form as they cross the yard a succession of arches facing on the one side
to southeast the other to southwest, and in the middle towards the south. On
the north side of the Point may be seen embedded in the igneous rock a piece
of stratified rock torn off doubtless by the flow of the latter as it broke through
the strata.

There is another good example of a dyke in a "gravel pit," or quarry, on
the northeast side of the hill on which " Upper Love " village stands. The
rocks here are in regular layers, dipping at a high angle (about 60 degrees) to
the east. The quarry looks east, and the dyke passes along its face in a waved
line from south to north. The dyke is about eighteen inches wide, is much
decomposed on its exposed edge and appears to slope downwards to the west.
It has been broken through by small faults (about six inches) in two places,
faults which obviously must have been caused by movements later than the

:^4 THE BUILDING OF AN ISLAND.

formation of the dvke. The ahove examples of dykes may be sufficient to
illustrate their character, the student will readily find others; but besides
appearing in the form of dvkes, the igneous rocks appear sometimes to have
been thrust up in considerable masses. The rocks at the summit of Mt. Eagle
appear to be of this kind.'*" At the cattle pen at the estate " Bugby Hole," a
great mass of cream-coloured rock, inclining to red, may be seen, which appears
to be the same rock as is so abundant along the south side of St. Thomas and
is called by Professor Cleve felsite. Around the works and the residence at
the estate Annaly, a rock appears which weathers to a white clav and, conse-
quently, has in some parts the outward appearance of a marl. It is a massive
unstratified rock of a verv pale green colour and has a semi-translucent appear-
ance. It is presumably a felsite.

At the bank by the side of the high-road at " Grange " and also on part of
the estate " Beeston Hill," there is a highly decomposed igneous rock which
contains a quantity of yellow mica in shining specks. A similar rock is found
at the estate " Hermitage." The mica is probably coloured by a trace of gold,
at all events the writer was shown, many years ago, a sample of yellow^ mica
sand which had been sent from St. Croix to London for expert opinion, and
which was reported on as containing gold, but not in any payable quantity.

Among the stratified rocks which are seen on " Blue Mountain, "t an
igneous rock has forced its way, and near to the summit of the mountain has
partly broken up the strata so that the fragments of these are seen embedded
in the intruded rock. This rock is fine-grained, grey in colour, and externally
resembles grey granite. It probably belongs to the same class of rocks as that
mentioned in the following paragraphs.

* The following notes were made by the present writer after ascending to the summit of this hill :
" Ascended from ' Hermitage ' to lower part of the ridge and then proceeded northwest and after-
wards west to the summit of Mt. Eagle. The whole slope of the ridge is covered with loose blocks and
smaller pieces of stone. Most of these show clear traces of stratification in narrow brown and whitish
brown bands. Mingled with these there are, however, many pieces of igneous rock, characterized by
numerous and rather large felspar crystals [probably felspar-porphyry]. The summit of Mt. Eagle shows
no stratification, but appears to be a compact or very fine-grained crystalline rock of igneous origin. The
rock is split by numerous cracks [joints], for the most part vertical and having the direction of east and
west."

t The following notes were made by the writer after ascending the ridge, as mentioned in the pre-
ceding note -.

" Passed along the ridge [Mt. Eagle Ridge] to Blue Mountain. Ascending towards the summit
found traces of stratification on the way up, dip east-southeast, at a high angle [70 to 75 degrees]. At
summit found same dip continued. The rocks here are in bands of a brown, whitish brown and light-blue
or slate colour. In one part the rocks appear to have been entered by greenstone and the strata seem to
have been broken up by it and the pieces mi.^ed with it. The greenstone is very fine-grained and is
e.^ternally grey. The stratified bands are mostly very thin and recall the rocks at ' Buck Island' and
some of those about ' Judith's Fancy '.

" Near the summit \oi Blue Mountain] on the northeast there is a protrusion of greenstone which
weathers light grey and looks much like grey granite. It is split by joints running north-northeast and
south-southwest at a high angle and by others at right angles. These joints are so regular that it is diffi-
cult to resist the impression that the rock is regularly stratified, yet the crystalline structure is perfect and
the composition of the two or three layjrs exposed seems to be identical. It is probably an intrusive sheet
of greenstone. This rock exhibits some beautiful hornblende crystals on the exposed surface."

THE BUILDING OF AN ISLAND. 55

At the estate " Southgate " and the neighbouring islet of " Green Kay,"
there is a great quantity of a grey rock which, in appearance, resembles granite,
being composed of white crystals with black oblong crystals among them. It
is, however, different from granite, for while that rock consists of the minerals
felspar, quartz and mica, the rock at the places named consists of felspar and
the dark mineral hornblende. On Green Kay, both the black .and the white
crystals attain in some places an unusually large size. The rock is called
gfreenstone or diorite.

Professor Cleve mentions the occurrence of diorite at Southgate and
Green Kay as well as elsewhere among the islands, and has some interesting
comments on the rock. He regards it as altered from the sedimentary rocks
by heat to such an extent that it has in some parts, but not everywhere,
become actually molten. He arrives at this conclusion from having found it
in the Virgin Islands, both interstratified with the other rocks without any
sign of intrusion, and also filling cracks in the surrounding rocks, in which
latter case it has evidently been intruded in a molten state.

Such a conclusion is probablv true of at least some other intruded rocks.
There is nothing to show that they come from any considerable distance lielow,
and it may well be that they are sometimes only the stratified rocks of the
neighbourhood which have actually been melted and thus made capable of
passing among the other rocks, following the direction of least pressure.

These rocks which we have seen to be thrust in among the stratified rocks
of our older formation in masses and dykes, though of volcanic character, are
not, strictly speaking, volcanic rocks, that is to say, they have not been thrown
out bv volcanoes. So far as the present writer is aware, there is no evidence
in anv part of our island of volcanic outbursts through the rocks we now see.
There is a strong probability, it is true, that the existing layers have been
formed from matter thrown out by volcanoes, either directly into the sea or on
to a neighbouring land from which they were washed into the sea, but there
appears to be no evidence anywhere of a crater or of the piling up of layers of
volcanic ash and cinders. If there were volcanoes at any time on the site of
what is now Santa Cruz, they have long ago been swept away in some of the
many changes that have passed over the solid structure of this beautiful little
land of ours, and no trace whatever of them remains.

At the same time the rocks in question, though not likely to have been
actually volcanic, consist of the same substances as make up the volcanic
rocks, and, as already noted, they have been in a molten condition.

Rocks of this class are often spoken of under the general name of " trap,"
an old-fashioned name but convenient for an amateur, since its use avoids the
necessity of any closer naming of the kind of rock, a task which must be left
to experts. The name "trap" is derived from the Swedish " trappa," a stair,
and was applied to this class of rocks because they are sometimes found to be
arranged in successive steps, formed from outflows whose spread became less
and less as they were successively pushed up amongst the strata, lifting the

56 THE BUILDING OF AN ISLAND.

upper beds. This formation of layers is especially conspicuo'us in the member
of the Trap group known as basalt, a hard, fine-grained black, sometimes
grey, rock, found in many parts of the world, as, for example, in the north-
east of Ireland and southwest of Scotland. It is over a layer of basalt that the
Zambesi in South Africa flows as it approaches the famous Victoria Falls,
about which it was formerly supposed that the wonderful cross-chasm into
which the river pours was produced by a great convulsion of Nature, but in
regard to which a recent observer has shown that both the chasm and the zig-
zag gorge, through which the river makes its way to the lower plain, have
been formed by the wearing action of the river itself, whose waters have cut
down through the basalt, the flow having followed great cracks which pass
across it. There do not appear to be any extensive overflows of basaltic or
other trap rocks in our islands, nor does basalt seem even to exist here, for
the hard black fragments which are sometimes found in the blue-beach con-
glomerates, especially in St. Thomas, are spoken of by Professor Cleve as " dark
porphyry or felsite."

Questions as to the names and characters of the igneous rocks ai-e, how-
ever, for professional geologists rather than for amateurs, who. unless they
have special knowledge, must be satisfied with the more general results of their
observations.

THE BUILDING OF AN ISLAND. 57

CHAPTER VII.

. Minerals.

The studv of minerals is an extensive subject in itself, nevertheless it is -
not difficult to acquire a few simple facts about them which will add interest
to our observations when examining the various rocks of our island.

What is a mineral? That is a (juestion not so easy to answer as mav at
first sight be supposed. In every-day language an3'thing found in the solid
part of our earth may be called a mineral; but in a scientific sense the word
has a more restricted meaning. The following definition and comments are
taken from the introduction to Nicol's Elements of Mineralogy: "In the
strictest sense, a mineral species is a natural inorganic bodv, possessing a defi-
nite chemical composition and assuming a regular determinate form or series
of forms. This definition excludes many bodies often regarded as minerals:
as, all the artificial salts of the chemist, all the inorganic secretions of plants
and animals, all the remains of former living beings now imbedded in rocks.
Some substances originallv organic products have indeed, by common consent,
found a place in mineral systems, as coal, amber, and mineral resins; but this
is a departure from the strictness of the definition, and in most cases had, per-
haps, better have been avoided. So also some amor[)hous substances, with
no precise form or chemical composition, as some kinds of clay, have been in-
troduced into works on mineralogv, but we believe often improperly, and with
no beneficial result. Aggregates of simple minerals, or rocks, are likewise ex-
cluded from this science, though the various associations of minerals, their
modes of" occurrence, and their geological position, are important points in
the listing of the different species."

The same author, in the beginning of his first chapter, in which he treats
of the forms of minerals, says: "Mineral substances occur in two distinct
modes of aggregation. Some consist of minute particles simplv collected to-
gether, with no regularitv of structure or constancy of external form, and are
named amorphous . '*" ''' '•■ '■' The other class have their ultimate atoms
evidently arranged according to definite law, and are named crystalline when
the regularity of structure appears only in the external disposition of the parts,
and crystallized, when it also produces a determinate external form or a
crystal^

In the limestone and marl formation of Santa Cruz and in the few lime-
stones of our oldest formations we may find a partial illustration of the above.
Frequently in the cracks of the limestones and in the small hollows in fossil
corals we may see an abundance of small crystals of carbonate of lime, crystals
which are known as calc-spar or calcite . The same substance is abundant in an
amorphous state (that is to say, without definite form), in the numerous concre-
tions of some of the beds and also in some of the more compact beds in their
entirety. The same crystalline limestone is, however, reser\'ed for those spark-
ling limestones known as marble, which have been produced in the earth by

58 THE liUlLUING OF AN ISLAND.

great heat and pressure from onlinarv limestones, a fact which has been estab-
lished b)^ the artificial conversion of chalk into marble under pressure in a blast
furnace. It does not appear that our Santa Cruz limestones, even in the
older formation, have been jilaccd under like severe conditions with the true
marbles. Professor Cleve calls these beds in our older formation merely
"compact limestone." In writing of the rocks in the smaller islands around
St. Thomas, he says, however, that "Congo Cav is a ridge of beautiful, hard
and crystalline limestone or marble, of a bluish gray colour and parallelopipedic.
structure." He also mentions crystalline limestone as found in St. John, be-,
tween Brown's Bay and Mary's Point, in Tortola, in Ginger Island and in
Great Hatch Island. From which it appears that by including our near neigh-
bors, islands which indeed, from a geological point of view, are included in our
system, we may find illustrations of carbonate of lime in each of its three forms,
amorphous , crystalline and crystallized.

In connection with this verv abundant component of our rocks there is
a point which, though somewhat obscure, is of such great interest as to be
worth a few lines being devoted to it. The removal of shells and corals im-
bedded in the rocks so as to leave hollows still showing their forms, must strike
every observer as a very remarkable fact. Why should these objects have
been dissolved out and have disappeared, while at the same time the mud in
which they were imbedded, and which consisted mostly of similar material
in a finely divided state, remains untouched by the dissolving agent? This
is a question for the mineralogist to answer, and it is answered by Professor
James Dana in his Manual of Geology.

Carbonate of lime, he tells us, forms two distinct minerals, calc-spar or cal-
cite and aragouite. The former mineral, as we have seen, is common in St.
Croix, but the latter does not appear to be found here in its crystallized form,
though, as we shall presently see, it must be fairly abundant. Aragonite takes its
name from the Spanish province of Aragon, where, as well as in some other parts
of the world, it is found in great beauty. It is crvstallized in thin prisms, hence
sometimes called needle spar, and is rather heavier than calcite. Professor
Dana savs that "shells, while consisting generallv of calcium carbonate, often
have a large part of the material in the aragonite state; and hence aragonite is
present through most uncrystalline limestones."

Further on, in his notes on " Chemical work," the Professor writes: " If
the fossils of a limestone are made of calcite and aragonite [the latter the pris-
matic calcium carbonate], the aragonite portion is taken away — a fact first re-
ported by Sorbv. Shells of the kind referred to are those of the genera Pinna,
Mytilus, Spondylus, Patella, Fiisns, Purpiira and Littorina, in which the inner
pearly layer- is aragonite, and the outer calcite. The shells of most Gastropods
and Cephalopods are aragonite ; and corals, including the millepores, are mainly
so; while shells of Rhizopods, Echinoderms and Brachiopods consist of
calcite."

Processor Dana further remarks: " When the minerals aragonite and cal-

THE BUILDING OF AN ISLAND. 59

cite are present together in a limestone, the first effect of metamorphic action
is the conversion of the aragonite into caicite." From which we may infer
that in those parts of our Hmestone formation where the fossils have dis-
appeared the aragonite has disappeared bv alteration into caicite and has been
added to the mass of the rock in this form ; whereas in tiiose parts where the
fossils still remain there is some aragonite yet present in the rock, justifying
the earlier remark (juotcd, in which aragonite is said to be "present through
most uncrvstalline limestones."

The present writer has not been able to find any rule for the occurrence of
limestone fossils in our island in the two forms mentioned — namely, as solid
fossils and as easts. A clcjse studv of the rocks and the fossils would probably
throw some light on the subject and would rcpav the reader who mav have
time and opportunity to follow up the subject.'-'

Quartz is a well-known mineral and occurs abundantly in the older of our
two formations. It is easily recognized by its great hardness, in which quality
it is exceeded by onlv a few minerals. Commonlv we can see that it has filled
up cracks in the rocks, and hence appears as white veins running irregularly
through them, while it sometimes forms six-sided crystals in the innermost
parts of the veins.

Flint is nearly the same substance as quartz — that is to sav, pure silica,
but is not, so far as the writer knows, found in St. Croix. It is in quartz veins
that gold is obtained in many parts of the world, but it does not appear that
the quartz veins of any part of St. Croix contain that precious metal.

As already mentioned, the chemical substance which forms quartz is silica,
which again is a compound of the elements silicon and oxygen. Quartz has
been deposited from silica in solution, and in some parts of the world it has
been deposited in large transparent crystals of great purity and beauty ; it is
then knowm as rock-crystal. Many beautiful stones used by jewellers, such as
amethyst, topaz, cornelian, jasper, etc., are onlv coloured varieties of quartz.
Our own island does not, however, appear to contain more than the simplest
forms of the mineral.

Felspai-, of wdiich there are several kinds, is a mineral that mav often be
seen as small white crystals in our older rocks; and in the rocks (jf the islet
called "Green Cay" it is seen in crystals of unusually large size. This
mineral, though not as hard as quartz, is still so hard that it is with difficulty
scratched by the point of a knife. Its chief constituents are silica and alumina.
Felspar occurs in an uncrystallized form in most of the older stratified rocks
of the island and in the igneous rocks. When decomposed it forms clay,
sometimes white clq,y, but more commonly broivn clay — that is to say, it is col-
oured by iron. Hence, it is from the felspar of the rocks that the clay which
forms a great part of the soils and subsoils in many parts of the island is
derived.

* The reader who may wish to verify the quotations from Professor Dana's Manual of Geology will
find in his inde,^, under Aragonite, references to the pages from which they are taken.

6o THE BUII.DIXG OF AN ISLAND.

Hornhle7ide is a dark-coloured, glistening mineral, very common in the
older rocks. Professor Cleve remarks that large crystalline masses are found
near Santa Cruz in the small Green Cay.

Mica is a mineral that crystallizes in tliin sheets, which in some countries
are sufficiently large and transparent to form to some extent a substitute for
glass. In our own island the mineral is found in tinv flat specks disseminated
through some of the rocks, as, for example, near Grange and Beeston Hill and
near Hermitage. In some places it has been sorted out from the other mate-
rials by the running streams, and may be collected in some quantity. Many
years ago the writer was shown a sample of such mica sand, which, on account
of its yellow, shiny appearance, had been sent to a London assaver for examin-
ation, and was jironounced by him to contain gold, but in too small proportion
to make the sand of any value.

Magnetic Iron Ore. On the sand of the shore near Fair Plain a black sand
may sometimes be seen in patches, and on examination of the particles thev
proved to be small crystals of magnetic iron ore. Here it is the motion of the
v^'^aves on the beach which sorts out the iron grains in this peculiar manner ;
but like the grains of mica sand, these particles have been derived from decom-
posed rocks of the Indurated Clay formation, and have been brought down by
the streams. This is a mineral which is found in many parts of the world, and
in some places is very abundant. As is well known, Mr. Edison has large
works in New Jersey for crushing certain rocks which are abundant there and
for separating the iron grains by sets of powerful electro-magnets, in front of
which the powdered rock is dropped in a continuous stream, the iron grains
being drawn inwards as they pass the magnets and so falling in a separate heap.
Afterwards the material is made into bricks for transportation to the iron
works where it is to be manufactured.

The minerals to which attention has been drawn in the above notes are
those which will commonly be noticed by the amateur while examining the
rocks of St. Croix.

So far as is known to the present writer, no valuable ores occur in the
island, which is not the same thing, however, as saying that there are none.
The writer, to say nothing of the rock exposures which he has not examined, is
not a mineralogist, and it is possible that he may have passed by some indica-
tions that may be recognized by an expert later. Molybdena and ores of
copper are found in the neighbouring island of Virgin Gorda, and the writer
has been told that galena (lead ore) containing traces of gold and silver has
been found in one of the St. Thomas Cays. Gold is also occasionally found in
the beds of some of the Porto Rico streams. With all these indications in the
neighbourhood, it may well be that some valuable metallic ores occur in St.
Croix. If ever found, the question will still remain whether they are worth
anything from a commercial point of view, a question which in the instances
named has been so far answered in the negative.

THE BUILDING OF AN ISLAND. 6 1

CHAPTER YIII.

The Sculpturing of the Island.

At the beginning of our study of the island we saw that the outline con-
sisted of three parts, a narrow triangle to the east, an oblong to the west and
a sloping neck connecting these two, but we did not then go further into
details.

When we now proceed to examine this outline more fully, one of the first
things that strikes us is that there are many projecting points or capes, and
on examination these points most often prove to be rocky, though not always
so, for we find conspicuous examples to the contrary in Sandv Point at the
southwestern extremity of the island and at Krause Point on the south shore,
both of which, except where the sand has been converted into rock, appear to
consist of loose sandy material. As a rule, however, the capes are rocky. And
we further notice that most of these rocky headlands are small hills, whose
seaward slopes have been cut away into cliffs by the wearing action of the
waves.

Fig. 22.

h.— Hilltop,
c— ClilT.

s. — Shore.

r. t. — Rockv table.

1. — Sea level.

At the foot of the cliff the sea has, moreover, ground down a rocky table
or platform, which now projects from the shore below the level of the water.
How were these platforms made ? The water alone could hardly have carved
them out of the solid rock, but we must remember that the water is continually
carrying sand and the stones previously broken out of the cliff backwards and
forwards over the rocky table, and that these can and doubtless do grind down
the surface. It sometimes happens, too, that off shore at such a point we find
that a small reef has been formed, its foundation being, in all likelihood, a still
earlier remnant of the projecting point. Between the capes there are bays
which sweep round in concave curves from cape to cape. The sandy shores
of these bays are mostly backed by banks of debris from the hills, and there is,
apparently, nothing to prevent the sea from carrying off both sand and debris
and so pushing the curve of the bay farther and farther back. As, however,
these curves remain pretty constant, it is plain that the sea must be prevented
bv some fixed law from doing this ; and the law is not difficult to discover.

62

THE BUILDING OF AN ISLAND.

The diagram (Fig. 23) represents two rocky points with a sandv bay
between them. Outside the points the general east to west current runs. If
the sandy shore were in a straight Hne with the points, the current would soon
remove a part of the sand and cut the shore back into something like the
curve indicated in the diagram, and we find that it has actually done so. But
whv does it not continue to cut it back ? Why does the outline of the bay
not recede still farther? It is because the current cannot penetrate any
farther, but creates a cou^iter-curroit in the bay, a current which, on its inner
side, is so sluggish that it would quickly drop any sand or mud which it might
have seized on.

An interesting proof of the existence and effect of tiie counter-current
may sometimes be seen when a small stream runs into the water of the bav
and brings down pebbles from the surface debris, in which case the pebbles
are deposited, not on the leeward side of the stream's mouth, as we might
expect, but on the windward side. They move against the direction of the
general current under the influence of the counter-current. This is shown in
the diagram, which fairlv represents an actually existing bav on the north
shore of the island. Storms may make small temporary changes in the curve
of such a bay, it is true, but when the usual daily conditions set in again, the
shore quickly regains its former outline.

Fig. 23.

^—

>.

fi

c ^

v^

*>f)

.0

^'

(1. c. — Direct current,
c. c. — Counter current,
r. p. — Rocky points.

sa. b. — Snndy lieacli.
sli. b. — Shingly beach,
s. s. V. — Seaside vesetation.

Onlv the wearing back of the rockv points which protect it can cause the
sandy shore of such a bay to recede inland. But this wearing back of the
rocks is undoubtedly always in slow progress, the rocky protectors are gradu-
ally driven back and the sandy shore must slowly recede with them. This
result is occasionally recorded by the beach limestone remainiag as an evidence
of the distance to which the shore has been recently pushed back ; a good
instance of which is seen in Christiansted harbour, between the Fort and the
mouth of the Lagoon, where a strip of shallow water, twelve feet or more in

THE BUILDING OF AX ISLAND. 63

width, intervenes between the present' sandy shore and a small reef of beach-
limestone, which marks a former shore-line.

Another evidence that the rockv points cannot for ever protect the shores
of the bays is found in the low cliffs formed of debris which in many places
has been washed from the hills by the rains, cliffs which show by their abrupt-
ness that an encroachment is being made upon them, as, for example, at Great
Pond, at La Vallee, and at Ham's Bay.

Thus we perceive that the sea is continually eating away the land at its
edges, and only requires time to bring it all down beneath the sea-level.

Even the reefs, which arc really magnificent protectors, because covered
by living coral, which is always able to maintain itself against the waves b)^ new
growths, and even in case of the gradual subsidence of the bottom can keep
the reef by such growth nearly up to the level of the water, yet these wonder-
ful reefs even cannot save the land from ultimate destruction, for the continual
currents and the occasional storms can work a way inside them and mav ulti-
mately leave them isolated out at sea, as most likely has been the case with the
reefs which we find a mile or two out at sea along our southern coast.

Sandy Points, like the two above-mentioned exceptional cases (Krause
Point and Sandy Point), can only exist under special conditions, the trend of
the coast and the existence of extensive reefs may direct the currents in such
a way that the sand is deposited, instead of being carried off'; but in the long
run these special conditions must be changed and the protected sandy points
will be removed as surely as are their rocky neighbours.

It appears, then, that granted time enough, the land could be eaten away
by the sea alone, but when we study attentively the agents that are at work on
the surface of the land, we shall see that if a considerable part of the wearing
away is due to the sea, a far greater part appears to be due to the rains and
the streams.

It is certain that the material which makes our present land has not been
put down in the sea in the form of hill and dale as we now see it, but that this
form has been given to it since its upheaval. Let us take, for the sake of
illustration, the hills at Anna's Hope and at Work and Rest, on opposite sides
of the Grange Valley (Figures 24 and 25). When we examine the strata in
these hills we do not find them taking the slope of the hillsides ; but we find
that they come out of the hillsides as though they wei"e once continuous across
the intervening valley, and the more we examine the question the more con-
vinced we shall become that such really was the case.

It seems, then, that the valley has been carved out of the uplifted strata,
and the hills are what is left behind. From this point of view it is the valleys,
and not the hills, which are the positive features in the landscape, and after we
have understood the facts connected with the elevation of our island, it is the
valleys which we must study first if we wish to know anything of the sculptur-
ing of its surface.

First, then, let us ask bv what tools the excavation of the particular valley

64

the building of an island.
Fig. 24.

/i.y.

^rOA'^a*^ l/aAJjLyci ■

How it is NOT.

Fig. 2:

How it is.

we have selected to examine has heen effected. Along the lowest line of the
vallev we find a small stream runninsj, which starts amonar the hills at the back
af Christiansted and runs into the sea, near the estate Hope. If we examine
the sides of the watercourse aionsf which this stream runs, we see that it is
mostly bordered by steep banks, and that these, first in one part and then in
another, are being cut down by the water accumulated in the brook after heavy
rains, so that the material which forms them is removed farther on and lodged
there and ultimately carried out to sea. It seems, at first sight, impossible that
this little stream can be the chisel which has carved out the wide vallev through
which it runs. Neither could it have done this great work without assistance,
but when wi- notice what happens over the whole vallev after a heavy fall of
rain, we shall see that a number of tiny rills run down the sides of the valley
from all parts, everyone of them muddy, and everyone of them, therefore, show-
ing its power to remove a modicum of the solid land and lodge it lower down,
ultimately to reach the sea. Every other valley in the island shows the same
thing. Let us look, for example, at the three or four small streams that come
down during heavy rains from the hills lying south of Christiansted; we find
them all carrying down mud, sand, and sometimes even stones, to the sea.
After such a rain the harbour is discoloured for a long distance from the shore.
If we then look up at the forms of the valleys from which these streamlets run
and from which the\' are carrying away all this material, we see that the main
vallevs all have numerous smaller valle\s which have been cut out of the

THE BUILDING OF AN ISLAND.

65

shoulders of the hills, and these again have still smaller valleys leading into
them, so that during rains the hills are drained by a multitude of small rills,
each of which is a tiny chisel, cutting the valleys deeper and deeper, and slowly,
but continually, lowering the slopes. It is to the action of such tools that we
owe the valleys. And while it is true that we owe the hills as masses to the
elevating forces, it is nevertheless mainly to the action of rain that we owe
their special forms, for the forms of the valleys decide that of the remaining
stuff which constitutes the hills. Nevertheless, the nature of the stuff itself has
much to say in deciding how the surface is carved out, as we shall presently
see. For there is another force at work, preparing the rocks for removal, and
that is the chemical action of air and water in breaking up or decomposing the
rocks, and the rate of this process varies greatlv, according to the nature of
the rock. Water and air find their way into the rocks through the cracks,
which, as we have already seen, abound in most kinds, and gradually change
their character. Finally, a soil is formed, generally full, however, of the small
fragments which result from the multitudinous cracks in the solid material,
for the most part, therefore, gravelly in the blue-beach formation, and often
filled with small limestone fragments in the marl formation. E.xamples of
both kinds maybe seen in the upper parts of gravel pits and marl pits in many
parts of the islam!. The soil thus formed is further divided bv the roots of the

Fi(

26.

A MARL PIT.

1. b. — Limestone beds.

m. — Marl (altered edges of the beds.)

s. — Soil (covering a layer of limestone fragments.)

countless plants which grow in it, and, dying in it, leave their decaying roots
to darken the colour of the soil with the carbon which the plants have col-
lected from the air. It is from these soils, of various degrees of poverty or
richness, that the little chisels running down the hillsides and along the bot-
toms of the valleys scoop out the modicum of the island which each is stealing

66 THE BUILDING OF AN ISLAND.

to carry lower down the slope and ultimately to the sea. We see that if such
a process is continued for ages it must reduce the general level of the island.
We also see that the process must be very slow, but must be especiallv so where
the rock is very hard and offers great resistance to the preparatory decompos-
ing action of the atmosphere. The points and lines, or the areas, where such
hard rocks exist, must come gradually to stand higher than the softer material
which surrounds them, and thus it is not difificult to understand that the forms
of the valleys, and consequently of the hills, is a good deal dependent on the
nature of the rocks.

Of this general truth we may occasionally find striking illustrations. For
example, when we drive past the residence of Diamond and Ruby we notice,
as we ascend the rising ground from the direction of Christiansted, that there
are many hard blocks of limestone lying by the roadside. We do not see,
in the cultivated fields, where these blocks have come from; but if we take the
road over Carrawall Hill and cross the same rising ground a short distance to
the south, we see that a rather thick layer of hard limestone is cut through for
the road where it nears the top of the rise. Here we see what it is that has
given origin to the large limestone blocks just mentioned, and what it is that
has protected this rising ground from the destructive action of the waters com-
ing from eastwards; and we see that the whole rise which, as a matter of fact,
ci'osses the slope of the strata and the consequent general direction of the drain-
age, owes its origin to the existence of this hard bed. In the same connection
it may be noted that the tops of the hills often show such hard rocks that we
can hardly conceive of their ever being worn away, yet the roughness of their
gray lichen-covered sides and their rounded angles give us a hint that, though
they may hold out for many centuries, they, too, must finally give way to the
destructive forces. Sometimes on the hillsides we meet with large isolated
blocks of stone of extreme hardness, whose form shows us that they have been
detached from layers of rock higher up the slope, and we wonder how they
can ever be worn away; but we, perhaps, find some of them still lower down
the hill, and we perceive that they must have been removed from above. But
how? Some day, after a storm perhaps, we get a lesson on this point; a large
block that we remember to have noticed on the upper side of a road, for ex-
ample, has slidden down and now partially blocks the road. This compels our
attention, and we reflect that these isolated blocks must in all cases be movina:
down the hillside in this wav. Every heavy rain removes something of the
soil and the gravel on which the block is resting, and by and by it slides farther
down, till finally it will reach the nearest watercourse. In such a watercourse
among the hills we may often find some of these large blocks from the slopes;
and what happens to them there? Why, that every flood in the watercourse
rolls along, bearing sand and pebbles in great quantities past them and over
them and grinding them down as the rush goes on, till finally they are worn
away and their particles are all carried off to the sea; it mav take centuries,
but it will be done.

THE BUILDING OF AN ISLAND. 67

The large blocks may especially attract our notice, but the smaller blocks
and those stones that break off from the limestone beds everywhere and cover
the surface over a large part of that formation, and the "gravel" of the older
formation, are, on account of their great abundance, of much more importance.
And in regard to them we notice that they must be continually shifted down
the hillsides and farther and farther along the plains, every heavy rain that falls
moving some of them, till they also are carried away to the sea.

The scattered blocks from the limestones are especially abundant on the
steep slopes of the hills which form the northeastern edge of the Central Slope,
but may be seen everywhere over the surface of the marl district. Sometimes
they are corals, but more commonly are only blocks naturally formed by the
jointing which we have seen both the limestone and the blue-beach layers to
possess. Smaller fragments from the strata fill the soil. In the older forma-
tion the pieces broken out of the layers of rock and the finer material result-
ing from their decomposition under the action of the weather, make up to-
gether a coating of debris over the bottom rock which sometimes' reaches a
thickness of from twenty to thirty feet, and effectually conceals the rock be-
low. Where this coating is shallow, as it commonly is on the slopes, the rills
sometimes cut through it down to the original rock and cut up a portion of
that rock to add to the gravelly covering. In the watercc^urses we can see
how this covering is brought down by the streams and rearranged to be again
carried farther on, till at last, though perhaps after the lapse of centuries, it
must eventually reach the sea.

We have seen, then, that over the whole surface of the island the destruc-
tive forces, chemical and mechanical, are constantly at work; but in any case
their action in lowering the general level of the country must be extremely
slow.

Perhaps it is next to impossible here in St. Croix, where the streams are
so short and so numerous, to come to any clear idea of the rate at which the
island is being cut down and carried into the sea, but in larger countries, where
the waste from extensive districts, or even great regions, is accumulated in one
large river and by it carried into the sea, it is possible to make a rough com-
putation of the amount of stuff carried yearlv to the sea, and with the extent
of the area known from which this stuff is brought, it is thus possible to say at
what rate the area in question, on the average, over the whole surface, is being
worn down. Professor Huxley tells us, for example, in his " Physiography,"
that the Thames carries yearly to the sea fourteen millions of cubic feet of solid
matter, and that the effect of this immense work is to lower the land of the
Thames basin by the eight-hundredth part of an inch in a year. In other
words, it would take 800 vears to lower the level of that tract of country by
the average amount of one inch, and nearlv ten thousand years to lower it a
foot. Ten thousand years ! And yet the difference in the landscape would
not be perceptible, except, perhaps, in some particular spots!

The rainfall in St Croix is double that of the Thames vallev, but in other

68 THE BUILDING OF AN ISLAND.

respects the destructive agencies are probably not greater, and if we allow
the results here to be twice as great as what is known in the Thames valley we
see that it would take 400 years to lower the surface of our island on the aver-
age by a single inch, and a similar statement, varying according to conditions,
may, of course, be made in regard to other lands. No wonder then that we
speak of the '' everlasting hills'' and regard everything as permanent. Yet it
is certain that there have been enormous destructions of the land masses — hard
masses, too, — in such a way that they have been ground down, not by a single
foot, but by hundreds, or even thousands, of feet, so that we can only conceive
that geological time must be reckoned rather by millions than by thousands of
years. What an immense period we must allow, for example, for the cutting
down of those enormous folds of tbe hard rocks of our older formation, which
we have seen must have formerly existed, but which have been planed down
to a small fraction of what they must once have been !

Such calculations as the above have, however, only a general value, for we
have no means of judging of the rainfall of the past,* neither is it possible to
state, except in a wide fashion, under what other conditions the destructive
forces acted ; we must, therefore, remain content with the general conclusion
which the study of the strata and the study of the present conditions force
upon us, namely, that vast periods of time must be allowed for the sculpturing
of the surface of our island into the forms which now adorn it. And this looks
no farther back than to the last elevation, when the mass of the "blue-beach"
rocks was thrust up bearing the limestone beds on its surface. And here we
are brought to a question which will considerably affect our conception of the
work which has been done and the time which has been taken in this last great
and still continuing process of the sculpturing of our island's surface. How
far did those limestone strata then lifted up extend over that surface ? Did
they extend over the whole of it, so that we must regard the blue-beach rocks
as onlv exposed to our view by the partial removal of the limestones? That
may have, indeed, been so. It may be that the whole of the east end and
north side of the island were covered with the limestone beds as well as the
centre and south which are now so covered ; but we have, of course, no right

• It should be remembered that the rainfall depends largely on the elevation of the land, and may
vary greatly among islands situated in the same geographical region and even when they are near to each
other. Porto Rico is not more than about 70 miles distant from Santa Cruz and very nearly in the same
latitude ; but it has elevations three times as high as ours, and in a large part of its mountain region the
rainfall is more than double ours.

In connection with this subject it may be noted that the July number of the Monthly Weather
Review for 1906 contains an instructive article from the pen of Mr. William H. Alexander of the Meteor-
ogical Station at San Juan, on the meteorology of Porto Rico, in which he gives a map showing the distri-
bution of the annual average rainfall in the island. Only in one part, lying along the south coast of
Ponce and its neighbourhood, is the rainfall so mTOiy as in St. Croi.x, namely, under fifty inches (ours is
about forty-seven inches) ; the fall is rather larger (fifty to seventy inches) in the e.xtrerae northwest, then
towards the interior, seventy to ninety inches ; still higher, ninety to one hundred and ten inches ; and
around El Yunque, the highest mountain (about 3,300 feet) the fall is over one hundred and ten inches. As
a consecjuence of the great rainfall, streams which are considerable in the rainy season run to the coa.st,
cutting out deep ravines and leaving sharp ridges between them. It follows that the work of levelling
must go on in Porto Rico at a much faster rate than with us.

THE BUILDING OF AN ISLAND. 69

to assume that it has been the case. That the limestone formation has orie-
inally been much thicker and much wider spread than we now find it is certain ;
but farther than that general assertion it does not seem possible to go.

As already said, we must allow long ages for the recent sculpturing of the
island before we get back to the time when the building up of the limestones
was completed and they were pushed up above the water ; but to these come
those other vast ages while the limestones were being extracted from the sea-
water by the several living agents and being built up slowly in the sea ; farther
back again, before those long ages of building, came the long ages of the earlier
destruction, when the great folds of the clay formation were everywhere being
cut down to expose the upturned edges, those edges which were to be lowered
into the sea and to receive the limestones ; lastly, we go still farther back and
contemplate the long-continued building up in the sea, most likelv from vol-
canic products, of the numberless strata that make up our clay or blue-beach
formation. How vast a period must thus have elapsed from the deposition of
the oldest visible layer of our island's rocks to the present time, when we see
those rocks being destroyed once more to be added again to the materials ac-
cumulating in the bed of the ocean !

JO THE BUILDING OF AN ISLAND.

CHAPTER IX.

Connection of the foregoing with the Physical Geography

OF the Island.

From our study of the stages through which our island has passed it seems
to be plain that its present form, both generally and in detail, must depend on
three things : firstly, the quality of the materials of which it is composed, next
the mode of its elevation, and thirdly, the mode of its sculpturing. The infor-
mation which we have been able to obtain on these subjects wnll help us to
form some conception of the way in which the existing physical features of the
island have originated.

In considering the elevation which followed the deposition of the lime-
stones, which we mav call the recent elevation, as distinguished from the earlier
elevation which followed the deposition of the blue-beach rocks, we see from the
form of the island that the main movement has been from about north-by-west.
In the Western Ohlong the arrangement of the limestone strata, as well as the
surface form, shows us that only one main wave of the earth's crust has been
produced here, namely, that which has resulted in the forming of the northern
chain of hills. When we pass to the Eastern Triangle we find a different con-
dition. Here it appears necessarv to assume that there have been two waves,
the northern wave being shown in Buck Island and the neighbouring bank,
the southern and more important wave in the East End range of hills. If
layers of limestone now covered the Hanks of this range as they cover the
southern flank of the northern hills, we should probably see these layers slop-
ing away on ecxch side of the range, thus revealing the second or southern wave
form which we assume to have been the cause of its formation.

The fact that the hills in the Eastern range arc seen to form three divi-
sions appears to be good evidence of two cross elevations, such as are found in
the central and west parts of the island, as revealed there by the dips of the
strata of the newer formation, and which would in all likelihood be similarly
revealed in the east, if the limestone now existed there. The crosscut through
the Christiansted Hills known as Spring Gut originated most likely in a split at
the top of the arch formed by these hills as they rose from the sea, or possibly
in a great north and south fault across the strata. It is a striking feature in
the local geography, and, as already noted, the " saddle " which it forms is
recognized as a well-known landmark for vessels arriving at the port of Chris-
tiansted.

The Neck shows a veritable break in the structure of the island, as may be
seen by the deep water forming a bay opposite to it, as well as by the existence
of the synclinal arrangement of the limestone rocks of the land. In the low
hills which at the back of the Princess Plain border the Central Slope the dips
are to southeast and southwest, so that there seems to be no evidence of these
beds forming an arch going over to northeast, unless, indeed, such evidence is
presented in the small Cay in Christiansted Harbour, which is entirely com-

THE BUILDING OK AN ISLAND. 7 I

posed of a conglomerate formed of well water-worn pebbles of the older forma-
tion embedded in calcareous mud, and showing apparently an irregular stratifi-
cation dipping towards the north. The attention of the writer has been called
to a bed of similar conglomerate which crops out on a grassy knoll to the east
of the road as it goes over the top of Evening Hill, and which possibly may
be a continuation of the deposit at the Cay. This conglomerate of the Cay,
although so small a deposit, has in any case great interest, and especially so if
further examination should show that it is not a recent deposit, to be reckoned
as only a little earlier than our beach and reef limestones, but that it belongs
to the great formation covering the centre and south of the island.*

It is, at all events, probable that the limestones of the Central Slope did
bend over to the northeast, and that the arch which would have revealed this
fact has been removed, perhaps in the first instance by the action of the sea on
the arch as it rose above the water, and later by the rains and consequent rills
which are still wearing back the hill front. Since the su])porting blue-beach
rocks must have shared in this arching, the comparatively low dip of these
rocks in some parts of Christiansted may possibly be due to it ; but on the
other hand it should be noticed that rocks of the same kind at Judith's Fancy
dip at about 45 degrees, so that fuller observation is needed before any clear
evidence in this direction can be adduced.

In regard to the Central and Southwestern Plain, the interesting question
arises, how far has it been formed by the sea and how far by surface drainage ?
That the sea passed through it at an early period in the course of the elevation
seems to be likely; but the present form of its surface is certainly due to the
streams which during rainy seasons course over it. The fact that sea-shells are
found in various parts of it is no evidence, as some observers have supposed,
that the sea has recently been there, those shells having undoubtedly been left
by the Caribs on their visits to the forests or to their cultivated grounds. This
explains the presence of all the bivalve shells and some of the univalves, while
many of the univalves, found in nearly all parts of the island, have been carried
inland by the hermit crabs, whose cast-ofT homes they are. That the present
form of the plain is due to the streams which cross it we may see from the
shallow depressions which those streams have formed and into which the water
on either hand runs, bearing away the soil so as to leavvC slightly rounded sur-
faces between the watercourse and its next neighbours.

The above remarks as to the action of the streams apply to all, or, at all
events, most of the plains in the island. The Parade Ground, east of Chris-
tiansted, though on only a small scale, furnishes an instructive example. If
in a dry time we enter the watercourse on the west side of the small triangular

* From an inset chart of Christiansted Harbour on Captain Parsons' Chart of Santa Cruz it appears
that "The Cay," called also Protestant Cay, is about 270 yards long from north to south and about loo
yards wide. Its highest point is 34 feet above sea-!evel. At its northern end are the ruins of an old fort
(Fort Sophia Frederica). There are also residences for the Pilot and his staff, and a large cistern with
collecting apron. In excavating for the cistern the same conglomerate was taken out as is seen on the
surface.

72 THE BUILDING OF AN ISLAND.

plain we find its upright banks to exhibit sections showing the gravelly debris
from the hills, and in some parts we find the watercourse widened, and we can
see that new deposits of the same debris are being laid down on its widened
bed. On the other (eastern) side of the Ground we find a similar, but aban-
doned, watercourse. It is nearly as deep as the western one, but big trees are
now growing in it, showing that no heavy current has passed along it for many
years. Possibly it may never be opened up again ; at present it serves only to
carry off the drainage from the adjacent hillslope and from part of the Ground,
which we may notice has a very slight rise in the middle. In earlier ages it is
not unlikely that the stream, which, as we have seen, now runs along the west
side of the Ground and formerly also the east side, wandered from side to side,
bringing down the debris and extending and levelling the little plain to the
form in which we now find it.

The way in which a stream may lower the surface of a plain is well illus-
trated in a watercourse which crosses the plain west of the estate Longford.
To the south of the highroad it will be seen that the stream is cutting into its
east bank, which shows vertical walls of debris that frequently break away and
fall into the watercourse in considerable masses, while on the west side there
are no such walls, and only at a considerable distance from the stream is there
even a sloping bank to indicate where the water has once been.

In connection with the plains we may consider the case of the lagoons
and seaside ponds. Krause Lagoon, on the south side of the island, is a rather
extensive area of islets and mudbanks, separated by water channels and ponds
connected with each other, and on its western side with the sea. The islets
and mudbanks are grown over with the red mangrove {RhizopJiora Mangle)
and the water is always more or less muddv. Along the seaward side of the
area we find a bank of sea sand of the ordinary character, but along the land
edge we find everywhere that the shore and the bottom are covered by clay
and fine gravel, which have been carried into the lagoon from the land. It
follows that the lagoon is being slowly but surely filled up by drainage from
the land. It will, at some future and distant age, become a plain. The streams,
which now rush in from time to time, spread out over it and drop their mud
all over its bottom ; but the streams of that future day will continue their
courses over it, partially cutting into it antl bringing the heavier debris to lie
upon it, and thus a plain of the onlinary type of the coast ])lains of our island
will be created.

The two ponds of Southgate and Great Pond are, in a similar manner, be-
ing filled up. Their existence seems to imply that after the plains, of which
they occupy the lowest i)art, had been formed by the streams from the hills,
there was a sinking of the land, producing bays of the sea, that the sea, in the
way described in an earlit-r chapter, then formed tongues of sand shutting in
the innermost parts of the bays and thus forming salt ponds or lagoons,
which have since been gradually filling up. The sand bar in each case is broken
through after heavy rains, when the accumulated water in the pond forces an

THE BUILDING OF AN ISLAND. 73

exit, but otherwise the bar remains permanent, and is covered with a strip of
the usual seaside veg^etation. There is a similar, but much smaller, pond at
the estate Coakley Bay.

The lagoon at Christiansted and the creek known as Salt River differ from
the ponds above mentioned in being deeper, the former having a depth of eight
or nine feet, the latter over twelve feet in the deepest parts; but thev, like the
other enclosed waters, are slowly filling up. The Christiansted Lagoon has two
branches, each of which ends in flat, swampy land ; and when we examine these
places we can see that it onlv requires time to extend this condition through
both arms and finally through the body of the lagoon. Salt River, in its inner-
most portions, shows the same tendency, and at its upper end are some fine,
flat, fertile lands that have doubtlessly resulted from a like filling up in earlier
times.

This "filling up" of several areas around the coast seems necessarilv to
implv a previous sinking of the land sufficient to form the ponds and lagoons
now being slowly filled. That such sinking has taken place appears to be con-
firmed bv the form of the bottom of Christiansted harbour, the deepest part
of which, passing through the Long Reef by the Ship Channel, seems only to
be a continuation of the watercourse coming down from the great rift in the
hills known as "Spring Gut." The channel is kept open, it is true, by quite a
different agencv, namelv. the outward current resulting from the accumulation
inside the harbour of the water dashing over the Long Reef ; but its origin
is probably as suggested.

A sinking, such as has been above supposed to have taken place, need not,
however, have been the last movement of the island's surface. The position
of the beach limestone, on which part of the town of Frederiksted stands,
seems indeed to imply a slight recent movement of elevation, if not general,
at all events in that part of the island.

When from a point of vantage we look down the course of one of the
larger valleys, such as that which passes through the North West Hills from
Mt. Stewart and opens out on the plain near Prosperity, we are struck not
onlv by the beauty of the landscape, but by its complications, and we get the
same impression when we turn to the map and see how the stream is here and
there turned aside, and how the spurs from the side hills come out into the
valley, leaving even at times what seem to be almost isolated hills. Yet there
can be no doubt that when the valley first began to be formed the case was
simple enough, the drainage merely followed the slope that had been given to
the mass by the elevating forces, whether the slope was given by a force act-
insf in one direction or whether it was the resultant of two or more forces actina-
in different directions. Hence when we have geological evidence of the direc-
tion of the recent force we generally find the geographical evidence to coincide
with it — that is to say, the streams run in the direction of the dip of the strata.
If they do not, there must be special grounds for the divergence, though per-
haps we may not be able to discover them. In general we have seen that this

74 THE BUILDING OF AN ISLAND.

agreement in these two classes of evidence exists in St. Croix ; but there seems
to be some divergence on the western edge of the Central Slope, where the
valleys, even on the extreme edge, as we now have it, do not tend inwards as
much as we should expect; while on the other hand the dip of the rocks turns
in more than we should expect from the direction of the synclinal axis. Does
not this suggest that the anticlinal axis of the Mt. Eagle Ridge has been lifted
considerably at a comparatively late period — that is to say, after the valleys in
question had been formed, or partially formed, and that this lifting has thrown
the dip of the strata more inwards ? This is, of course, only a speculation, and
is here mentioned merely as a possibility that may be worth attention.

The observer who becomes interested will find everywhere among the
physical features of the island matter for inquiry, and after a time will see in
the hills, the valleys and the plains old friends about whom he already knows
something and concerning whom he is always eager to learn more.

THE BUILDING OF AN ISLAND. 75

CHAPTER X.

Relation of the Structure of St. Croix to that of the
OTHER West Indian Islands.

A glance at a map of the West Indies shows that the islands are arranged
along two great lines or axes, one lying east and west, the other lying north
and south ; the former shutting in the Caribbean Sea on the north, the latter
shutting it in on the east.

The great east and west axis, about 1,200 miles in length, divides in the
island of Hayti, in a westerly direction, into two branches, one passing along
the northern peninsula of the island and through Cuba, the other passing
along the southern peninsula and through Jamaica. From Hayti the undi-
vided axis passes eastward through Porto Rico and ends in a group of small
islands, of which St. Croix is one. St. Croix belongs, then, to the east and
west axis of the West Indies.

The north and south axis, about 500 miles in length, consists of a curve
of volcanic islands, the curve being convex to the open Atlantic. The islands
rise rather abruptly from the Caribbean Sea, but have on their eastern side
towards the north two wide banks from which rise several non-volcanic islands.

The obvious points of contrast between these two axes are, that one has
for the most part large islands along it, with hardly any volcanos, while the
other has in its main line only small islands, all of which have one or more
volcanos, mostly extinct, it is true, but some of them, as recent experience
has proved, still capable of tremendous occasional activity.

Our examination of the structure of our island revealed two great periods
of elevation, one since the deposition of the limestone formation, and another,
an earlier period, following the deposition of the blue-beach rocks. In both
cases the position of the layers showed that the principal pressure came from
the north ; in the earlier movement it was from north-northeast, and in the later
movement it was from north-by-west. We may be sure that there were
definite causes, not only for the movements both being from the north, but
also for the difference of three points in the direction of the two movements,
though we may not be able to discover what the causes were.

In this connection it is interesting to note that east of Porto Rico the
island of Vieques (or Crab Island), nearly as long as St. Croix, lies almost
parallel to it, and has, therefore, probably been lifted on the crest of a wave,
pushed up by the same movement as that which has lifted our island. Whether
there is any geological evidence in Vieques for this theory, the present writer
is unable to say. Professor Cleve, after saying that he was in the island only
for a few davs and under very unfavourable circumstances, so that he knows
very little about its geology, remarks as follows: " Near the shore of Puerto
Mula an altered dark green rock is visible, but at a short distance from the
coast occurs syenite-like diorite, which seems to be the most important rock
of the island, producing by alteration a very fertile soil. The diorite has the

76 THE liUILDING OF AN ISLAND.

same appearance as the rock of Virgin Gorda, and has, also, a sj)heroidal
structure. In the eastern part of the island some stratified white rocks seem
to occur, hut liaving seen them only from the sea, at a considerable distance, I
cannot give any description of them." From our present standpoint it would
be very interesting to know something about those " stratified white rocks."

Turning to our sister island of St. Thomas, 40 miles away from us to the
north, we find no "stratified white rocks" there to help us. St. Thomas has
the older set of our Santa Cruz rocks, but the younger set (the limestones) are
entirely wanting. Possibly they were lodged there on the top of the older
rocks, but have been since washed away, as perhaps they were, from the tops
of the northern and eastern hills of St. Croix. However that may be, it is
certain that the limestone system of St. Croix is entirely wanting in St.
Thomas, and consequently we lose the geological evidence as to the direction
of the later tipheaving force. About the direction of the more ancient upheaval
we have, however, very good evidence, and it is extremely interesting to find
that the ancient rocks have been thrust up in ridges or waves, lying parallel to
the like waves in St. Croix ; in other words, the St. Thomas rocks have been
subjected to the same thrusts as have acted on the similar ancient rocks of St.
Croix. For evidence of this we have the quarries and other rock exposures
in and about the town. In a quarry on the west side of the " Field" we find
plainly stratified rocks of the indurated clay type, much like those we see near
Christiansted, and we find that they dip at a high angle (about 40 degrees) to
about northeast. Across the " Field," on its eastern side, we find another
quarry showing hard blue-beach conglomerate. Most of the embedded frag-
ments are somewhat rounded, as though water-worn, and the mass is so thick
that we at first discover no stratification, but after a careful search, we find in
the northwest corner of the quarrv some fine-grained blue-beach without
embedded pebbles, and showing ribbon-like markings indicating stratification,
the layers dipping in the same direction as those of the first-named quarry.
When we ascend the hill towards Louisenhoi and Ma Folic, we see similar
indications of the original stratification of the rocks and of the dip being to
about northeast. But when, starting from our first named quarry, we move
southwards towards the town, we soon meet (near the Epidemic Hospital)
with similar indurated cla)^ rocks distinctly stratified, but dipping, not to north-
east, but to so2ith or south-by-east. If we ascend the road up the hill to the
west we shall find further evidence of this southerly dip, and we shall meet
with it here and there in various parts of the town. Hence we have dis-
covered that the town stands on the south slope of a wave of the old rocks,
which, immediately behind it towards the north, has been cut down into a
slight depression, while the northern slope of the wave appears just beyond
and in the higher hillsides.

This wave in the strata is of especial interest, because it appears, in the
hardness of one of its beds, to be the cause of the peculiar hill spurs which
have given the opportunity of building a considerable part of the town on

THE BUILDING OF AN ISLAND.

n

three small hills, thus giving rise to the pieturesque appearance so greatly
admired by visitors to the island. Many residents must have noticed the great
blocks of rock that lie about the uppermost parts and back slopes of the
middle and eastern hills, as well as the fourth hill, still farther east, on which
"Blue Beard's Castle" stands. It is obvious that these blocks are from the
broken edges of a thick and hard stratum coming up at a moderate angle from
the south. The somewhat softer rocks below this bed have been cut away
where they crop out beyond it towards the north, so that a slight hollow has
been made there in each case, most marked behind the easternmost hill, where
it is occupied by the street known as " Polyberg."

If we add to the above observations one from Professor Cleve's account
of St. Thomas, we are introduced to a repetition of the northern of the two
above named dips. The Professor writes of the blue-beach rock: "In the
harbour near the fort and on the small cay of Prince Ricpert the rock forms
regular strata of half a meter (nearly 20 inches) in thickness. Their strike is
S.S.E. — N.N.W. and dip 30 degrees to E.N.E." Putting this observation
with those described above, we may illustrate the probable positions of the
strata in a rough way by the accompanying diagram (Fig. 27), in regard to

Fig. 27.

which it will, of course, be understood that only the position of the anticlinal
axis to the back of the town can be given with any approach to accuracy ; the
synclinal axis must come somewhere between the town and Prince Rupert
rocks, but cannot be more closely indicated, at all events not without fuller

investigation.

It seems then pretty clear that the ancient elevation of the rocky masses
in St. Thomas has been brought about by the same force as has raised the
ridges of the older rocks in St. Croix, and the possibility at once presents itself
that the force is the same as has at first pushed up the whole great east and
west axis.

There was, no doubt, a recent lifting of St. Thomas at the same time as
the corresponding lifting of St. Croix, that is to say, after the deposition of
the limestones ; but as St. Thomas lacks these limestones, we can only judge
of the direction of the force from the form of the island, and the line of its
length would seem to justify the belief that the recent force of elevation has

78

THE BUILDING OF AN ISLAND.

acted in the same direction as in the ancient elevation, that is to say, from
about north-northeast, and not, as in St. Croix ( ? and in Vieques), from north-
by-west.

The existence of an unusually deep sea channel between the two islands
need not present any difficulty in supposing the action, on both sides of the
channel, of the same pressure through the earth's crust. When we find, on
the chart, depths of i loo, 1500 and even 2500 fathoms, we may at first think
of these depths as indicating a great chasm in the earth's crust, so great that
it would cut off the possibility of any pressure being exerted across it ; but
when we compare these depths with the width of the channel (40 miles) we
see that there is not such a great depression after all, and the difficulty disap-
pears. (See Fig. 28.) Besides which, we must remember that the deep
channel may not have existed when the early upward movements took place.
Indeed it is probable that this remarkable channel is of quite recent origin.

S^C

Fig. 28.

V?/^i2*vM..tyL- .

<J^r.

The foregoing observations are sufficient to show the connection between
the structures of the two islands. There are, however, some differences.
Professor Cleve describes the distribution of the rocks of St. Thomas as in
three bands, the most southerly, as shown along the coast and in the islets as
far west as Little Saba, he describes as felsite (with blue-beach subordinate).
The felsite is a verv hard rock, usually of a creamy white colour with much
red in it. The south side of Little Saba, as seen from the sea, presents a
striking: exhibition of this rock. The Professor remarks in reijard to that
islet, that it is commonlv supposed to have been a volcano, which, he says, is
not correct, "The rock being of the same kind as at Red Point, a fine-grained
felsite, sometimes altered to kaolin." There is very little felsite of this kind in
St. Croix. The strip beyond this felsite strip, to the north, is described by
Professor Cleve as "blue-beach with felsite subordinate." It is this strip to
which the rocks of the town and the central hills already considered belong.
Lastly he mentions a band of "stratified metamorphic rock (clay-slate, etc.)"
stretching along the north coast from Northside Bay to Coki Point in the
east, a strip which may be compared with the clay-slate of St. Croix. The
Professor remarks under the head " Blue-beach " (page 40) : " It is very likely
that the clay-slate of the Virgin Islands is only an exceedingly fine-grained
variety of blue-beach."

THE BUILDING OF AN ISLAND. 79

The islands of St. John and Tortola, to the east of St. Thomas, much re-
semble the last named in their rock structure, only that the strike of the strata
lies east and west. Virgin Gorda differs mainlv in exhibiting a large area of
unstratified diorite, which is often mistaken by visitors for granite.

Anegada, which ends the chain, is, however, quite different from the other
Virgin Islands, being a flat island entirely composed of limestone of quite re-
cent date, as shown by the fact that it contains onlv shells of species which
still live in these waters The Bahamas, which are commonly regarded as a
continuation of the Caribbean axis, are of similar structure.

Before turning west to the large islands, it will be interesting to notice
that, judging from Professor Cleve's observations in Anguilla, St. Martin's
and St. Bartholomew, those islands belong, not as we might have expected, to
the great volcanic axis, but to our own east and west axis. He says, namely,
that the dips of the rocks in St. Martin's and St. Bartholomew are to the south ;
and about Anguilla he reports that in the abrupt cliffs of the northern coast
the rocks on which the limestones of the island rest may be seen ; it is a kind
of trap. From these observations it would appear likely that there has been a
continuation of the great axis eastward and that this has been connected with
the pressures which have raised those three islands.

When, however, we leave the bank on which the above islands stand, and
arrive, going southward, at Antigua, the case is quite different.*

In Antigua the tilt of the strata is from the southwest and they dip away
to the northeast. Antigua is, therefore, geologically a dependencv of the north
and south axis. The island shows three sets of rocks, two of them of ultimate
volcanic origin, the other consisting of limestones and marls originating in the
ocean. As in St. Croix, the older rocks have in a past age sunk into the sea
and have had the limestones deposited upon them. There are, however, con-
siderable differences. The older formations do not appear to have been raised
into ridges as in St. Croix, and the limestones have, therefore, not been laid
down on the edges of the older formation, but on the surface of their upper-
most beds. Another great difference is that the upper part of the older rocks
(the second of the two groups) is all clearly stratified, consisting of regular
beds, mostly of hardened clavs and sandstones, and has not undergone any
marked alteration as a mass. On the other hand, some of the beds have been
silicified in a remarkable degree. The conversion into silica has taken place
in some of the marine limestones interstratified with the clays, in which we
may find corals and shells partially or entirely converted into flint ; it has also

* Reference to a chart of the West Indies shows that Antigua and Barbuda, its dependency to the
north, both stand on a bank lying north and south. Barbuda is a flat island, having an elevation along
the east shore known locally as the Highlands, the highest point of which is given in the chart as 115 feet.
The rocks in that part probably belong to the same formation as the limestone rocks in the north of Antigua,
all the rest of the island is made up entirely of a recent limestone, full of shells of the same species as now
live in the adjacent waters, and to be compared with the recent limestone of Fredenksted. The writer
has seen there the ruins of an old castle, all the stones of which had been cut from the limestone of the flat,
and were full of small shells which could be matched from the shore of the neighbouring lagoon.

8o THE BUILDING OF AN ISLAND.

happened in beds laid down in fresh water ponds, where fresh water shells along
with the beds themselves have been similarly converted; and associated with
them a great quantity of fragments of various species of wood have been so
perfectly preserved in the form of agate that the minutest details of their
structure are beautifullv exhibited.

The amount of silica in solution during the deposition both of the strati-
fied clays and the later limestones, must have been enormous, for besides the
silicified beds and fossils, both marine and fresh water, already mentioned as
lying among the clay beds, the present writer has seen in the limestones of the
Northwest true flints resembling those found in the chalk, and has seen on the
north side of the islet known as Long Island a beach of rolled flint pebbles,
very much like such beaches on the south coast of England.

It appears, then, that while the islands of Anguilla, St. Martin's and St.
Bartholomew are possibly to be regarded as geologically belonging to the same
axis as our own island, Antigua and the more southerly non-volcanic islands,
'including Barbados, are related to the other great axis, namely, that of the vol-
canic chain.

When we now turn westward and follow the chain of the larger islands,
.we find that all of them, from Porto Rico to Cuba and to Jamaica, have ex-
tensive limestone formations on their seaward slopes and even high up in
the mountains, while the central and highest parts are formed of rocks some-
what similar, and in some cases very similar, to the older rocks of our own
island. These older rocks in the several islands have also been commonly
pushed up at high angles, are much altered and contorted, and are penetrated
by igneous rocks just as the older rocks of St. Croix. From all which it may
be concluded that the principal events in the geological history of St. Croi.x
have been common to the whole line of the larger islands. They too have
been pushed up, have been denuded, have sunk again and have received the
limestone beds on the worn edges of their strata, and then have once more
been forced up above the level of the sea.

Hence we see that the east and west axis of the West Indies is a great
mountain chain, which has probably been raised as a whole by the same forces
acting through its whole length. We can already see, however, in the differ-
ent heights of the various parts, evidence that the conditions have not been
alike in all of them ; and a detailed studv of the islands would no doubt reveal
many important differences.

Investigations concerning the distribution of the plants and land shells of
the West Indies have shown the great probability of the islands and the banks
from which they rise having at one time been continuous land, and having
since sunk so as to allow the water to flow over some of the cross valleys and
thus to break up continuous chains of mountains into chains of islands. The
depths in manv of the channels between the islands exceed a thousand fathoms
or six thousand feet. When, however, we recall what we have learned from
the studv of the St. Croix rocks, about cross elevations and depressions, it

THE BUILDING OF AN ISLAND. 8 1

seems not impossible that the present considerable depths of water in some of
the channels may be the result of local depressions, so that, although it would
take a preneral rise equal at least to the above-named depth to bring the bot-
toms of the present channels above the sea level, it does not follow that the
sinking of the land in its entirety by that amount has been necessary to cause
the existing separation.

Some sinking appears, however, highly probable, and we have already
found, while discussing in the last chapter the ponds and lagoons of the island,
that these present some local evidence for such a movement, which, however,
would probably be the last stage only of the larger movement supposed to be
revealed by the present distribution of the plants and land shells.

So far we have seen that the geological history of St. Croix appears to be
bound up with the history of the formation of the east and west axis of the
West Indies, but there still remains the question: In what relation does this
axis stand to the great north and south axis? As the answer to this question
involves some wider considerations than any yet taken up in these pages, it is
best to leave it over for the next chapter.

§2 THE BUILDING OF AN ISLAND.

CHAPTER XI.

The Relation of the Geology of St. Croix to Geology

IN General.

The reader who may wish to extend his studies to the construction and
history of the earth's crust as shown in other parts of the world will find valu-
able help in such works as Huxley's Physiography and Marr's Introduction to
Geology, or, if desirous of following up the subject more fullv, then in Lvell's
Principles of Geology and Dana's Manual, but for the sake of others who may
wish only a brief statement of how our local geologv stands to geology in gen-
eral the present chapter is added.

The subject appears to fall naturally into three parts; for we mav com-
pare the rocks of St. Croix to those of the world in general — firstly, in regard
to their modes of origin ; next, in regard to the times of their origin relatively
considered, or in other words, then- relative ages ; and lastly, we may compare
them in regard to their subsequent history.

I. — Origin of the Rocks.

In our examination of the St. Croix rocks we found that nearlv all of them
had been laid down in the sea, and must therefore be classed as aqueous or sed-
imentary rocks, but that there were a few which had evidenly been forced up
from below in a molten state, and must therefore be classed as ioneotis rocks.
Both these great classes of rocks are found in all parts of the world, some of
them much like those of our own island, but others very different from them. /

Igneous Rocks.

Most geologists have agreed to arrange the igneous rocks in two great
classes, namely, the Plutonic and the I'olcanic.

None of the Plutonic rocks appear ever to have been thrown out b\- yoI-
canoes, but they seem to have been formed deep down in the earth's crust,
hence their name, from Pluto, the god of the lower regions. The chief mem-
bers of this class are the various kinds of granite. The composition of granite
varies somewhat, but commonly it consists of the minerals felspar, quartz and
mica in distinct crystals. It is a very important rock, and was formerly sup-
posed to be the oldest of rocks and to form the base rock of the earth's crust,
and, although this view has since been modified by the discovery of granite
among the later formations, there can be no doubt that it is verv widely dis-
tributed and that it has afforded by its decomposition a considerable part of
the materials of the stratified rocks. Some granite is extremely hard and slow
to change, but there are other kinds which decompose rather easily; the fel-
spar decomposes to a clay, the finest being known as Kaolin, the clay from
which fine porcelain is made. When rills pass over the decomposed granite
they wash away the clay and redeposit some of it in beds, carrving the rest ulti-

THE BUILDING OF AN ISLAND. 8

:>

mately to the sea ; the quartz crystals are separated from the mass and may be
redeposited, and if they reach the sea they are rolled on the beach till their
edges are removed, and they may then come to form beds of quartz sand on
the sea bottom.

Granite is exposed in great and widely extended masses in many parts of
the world and is sometimes found to have been thrust in between layers of
stratified rocks, or to have been forced through them as dykes and veins. The
present writer has not seen granite in any form in the St. Croix formations,
but Professor Cleve mentions granite veins as occurring in several of the islets
around St. Thomas and in Tortola.

Another important rock, which also contributes largely to the supply of
material for the stratified rocks, is gneiss. It consists of the same kinds of
crystals as those which make up granite, but the crystals are more or less ar-
ranged in layers, sometimes with barely a tendency to that form of arrange-
ment, so as hardly to be distinguishable from granite. Where, on the other
hand, this arrangement is strongly marked it suggests that the rock has first
been stratified and afterwards altered by heat. Many geologists, however, are
of the opinion that at least some kinds of gneiss, and possibly all kinds, are
true igneous rocks that have rearranged their constituents under the action of
heat and pressure; that they are, in fact, altered igneous rocks.

The Volcanic Rocks. — Dr. J. W. Spencer, writing about the recent earth-
quake in Jamaica, in the magazine "Science," for June 21, 1907, after pointing
out that the earthquake could hardlv have been due to volcanic action, since
Jamaica is far removed both from the West Indian and the Central American
volcanic chains, adds : " Moreover, Jamaica is not volcanic, with only one Pli-
ocene volcano upon the northern coast." If there is one extinct volcano in
Jamaica it is possible that others may be found in Cuba and Hayti when those
islands come to be more thoroughly examined. However that may be, the
east and west axis presents a great contrast to that which lies north and south,
for, while the former has one volcano and possibly a few more, the latter is full
of them. Most of these show no signs of activity and may be regarded as ex-
tinct ; others are evidently only slumbering, and in the case of Mont Pelee in
Martinique and the volcano of St. Vincent the eruptions of 1902 proved how
disastrous their occasional outbursts can be.

Many of the West Indian volcanoes, perhaps nearly all, have distinct
craters, but this does not commonly appear in a distant view. One of these,
however, namely, that of the island of St. Eustatius, is a tvpical volcano. A
sight of it is very instructive, for not only do we get a hint of the way in which
the material far down in the earth's crust may be brought up and piled on the
surface, but in the numerous ravines that score its slopes we see how the rains
may eat into and remove this material and finally level the great pile which the
volcanic force has built up The St. Eustatius volcano is about 2,000 ft. high.
From some points of view, both on the island itself and on the neighbouring
sea, the crater can plainly be seen to form a hollow, and the volcano is locally

84

THE BUILDING OF AN ISLAND.

known by the expressive name of "The Quill." The diagram (Fig. 29) shows
an outline of it as seen from the north.

v / V>

%■ M-

^ca. <dO.

In some cases the conditions during a volcanic eruption are such as to
permit of a spectator remaining on, or even within, the edge of a crater during
the eruption. In this respect Stromboli, in the Lipari Islands, which has re-
cently (May, 1907,) astonished the world by its activity, has hitherto presented
a specially favorable field of study, because, although nearly always active, its
activity has usually been of so moderate a character that the explosions which
take place at short intervals at the bottom of the crater could be watched with
very little danger to the onlooker. In this way it has been found that when
an explosion is about to take place, there rises on the surface of the molten
rock at the bottom of the crater a large bubble, which explodes, emitting a
cloud of steam and of dust formed by some of the matter being blown into
minute fragments. The explosion reveals the glowing molten mass below,
and this lights up the column of steam and dust that has been thrown out
from the vent, and thus gives rise to the popular but mistaken notion that
flames issue from the crater; The dust produced by the explosion is known
as volcanic ash, a name to which there can be no objection so long as we
remember that there has been no combustion of any solid substance and that
therefore the volcanic dust cannot be ash in the usual sense of the term.
Where does the steam which causes the explosions come from ? Formerly
it was supposed to be from the surface water of the earth, which was
thought to have reached the hot rock through cracks, but it is now generallv
believed that it comes from the rocks themselves. Chemical analysis shows
that they contain a considerable portion of water, not as a separate substance,
hut in combination with other components of the rocks. The intense heat

THE BUILDING OF AN ISLAND. 65

releases this water, which comes away as steam as soon as the pressure on
the overlying mass is sufficiently reduced by the approach of the highly
heated matter towards the surface. The same may be said of the carbonic
acid gas which is often found to come awav from the craters and occasionally
the sides of volcanoes.

There is good reason to suppose that the more important eruptions, even
the mightiest, are caused in a similar way to the smaller and more frequent
explosions in the crater of Stromboli. When a volcano remains (juiet for
some time, the molten rock in the upper part of the vent cools down and
becomes solid ; but when the mass below melts again the same pressure as
before is set up, and as the melting process proceeds upwards the weight of
the overlying rock at last becomes too small to prevent the explosion, which
then takes place, shattering the plug at the top of the vent to fragments and
throwing these high into the air, sending up at the same time a portion of the
molten rock, blown into fine particles. The rush of steam and gas from the
vent is often powerful enough to carry the finer particles several miles high,
so high that in the West Indies they reach the region of the return trade-wind,
where they then drift eastwards with the current, and may travel, as in the
case of the several recorded eruptions of the St. Vincent volcano, several
hundreds of miles in that direction, the St. Vincent ash falling not only on the
island of Barbados, but on the decks of ships far out on the Atlantic. If they
are not thrown to so great an altitude as that named above, they may yet be
shot so high up in the trade-wind current that thev are carried along by it for
hundreds of miles, as was the case during the Mont Pelee eruptions in 1902,
when ash from the mountain was brought down by showers of rain in St.
Croix and St. Thomas, Martinique being distant more than 300 miles to the
southeast, and even in Jamaica, more than a thousand miles from the scene of
the explosions.

The heavier ash and the stones of various sizes are, of course, not carried
so far, but fall around the vent. It is in this way that the cone and the crater
are formed. The theor)^ of their formation is indicated in Fig. 30, where we
must let the few lines showing how the cone is built up, stand for thousands
of thin layers of stones and ashes. The successive showers of stones and ash
deposit most of their material not far from the vent, some of it slides down
again inwards as well as outwards and in this way the cup-like depression as
well as the cone is formed.

It sometimes happens in volcanic outbursts that the molten rock wells up
into the crater, breaks part of it down, and then moves slowly down the
mountain side. The flow constitutes a stream of lava, a true volcanic rock.
Such a stream is genei"ally full of small holes, caused by steam and gas ; but is
denser towards the middle than on the surface. Such flows of lava sometimes
occur within the mountain instead of down its sides, the molten rock spreading
itself in sheets between the beds of ash ; sometimes the pressure within causes
upright cracks around the vent, and into these the molten matter is forced

86 THE BUILDING OF AN ISLAND.

from below, giving rise to dvkes. It may be asked how such facts as these
last mentioned can be known? They are learned from old craters antl from
the valleys which are sometimes cut out by streams in volcanic districts and
reveal the structure of the mountain slopes; particularlv has this been the case
with the ancient and long extinct volcanoes of Auvergne in Central France,
where, although the cones and craters have been preserved, the mountain sides
have been scored by streams, whose eroding action has opened up to the
student of volcanoes many of the secrets of those wonderful natural agents.

As already remarked, there are no evidences of the existence of volcanoes
in St. Croix; if there have been any they have been long since swept away,
yet, as we have seen, there are abundant evidences of the action of heat, by
which most of the older sedimentary rocks have been greatly altered and by
which dykes and masses of igneous rock have been thrust in among the stratified
rocks.

These igneous rocks of St. Croix, not being plainly of volcanic origin,
would be placed bv some geologists in a third class, intermediate between the
Plutonic and the Volcanic, but as very similar rocks can be shown in some
parts of the world to have been formed below volcanoes, it seems hardly, nec-
essary, so far as the rocks themselves are concerned, to make the distinction.
If it is made, the igneous rocks of St. Croix mav be described as trap rocks,
and the question of their possible connection, or the connection of some of
them, with ancient volcanoes, may be left open.

Geologists have found that volcanoes have existed from very far back in
the history of the earth's crust. Those of the West Indian north and south
axis appear, however, to have originated in a quite recent geological age, the
around for which conclusion will be mentioned later.

The origin of the heat which causes volcanic activity, as well as such
alterations and such intrusions of trap as we find in St. Croix, has been much
discussed. Some have supposed that the earth's crust rests on a globe of
molten rock, which here and there oozes upwards and sometimes comes out
on the surface ; but it has been shown that this is impossible, since a crust so
situated would be racked to pieces by tidal movements in the fiery ocean
below. Others have supposed that, although the earth has so far cooled down
that there is no such central ocean of fire, there are local patches of molten
rock, from which the supplv in the volcanic vents is derived. This view is
still held by some geologists, while others maintain that the heat is developed
bv chemical changes in the rocks and by alterations of pressure as the earth's
crust contracts, differences of opinion which show us that while the effects are
known the causes are still obscure.

The Sedimentary Rocks

Having seen the relation in which the few igneous rocks of our island
stand to the class generally, we may now consider the relation as it concerns
the orisin of the sedimcnlarv rocks. It will be recalled that these rocks in St.

THE BUILDING OF AN ISLAND. 87

.Croix belong to two very different sets, the younger set being of organic
origin, that is to say, derived from hving creatures whicli had extracted the
lime of the hard parts of their structure from the sea-water ; the older set
being of mechanical origin, the material of its beds having been washed down
from the land into the sea. Both these two great classes of sedimentary I'ocks,
the organic and the inorganic, have their representatives all the world over.
Let us first compare some of these with our own and afterwards see whether
there are not other great groups of sedimentary rocks, which are not at all
represented in St. Croix.

The Lime Rocks.

Varieties belonging to this class are common all over the world. One of
the best known is chalk, frequently, though not always, a soft rock. It is
mostly composed of minute shells and fragments of these, and many of its
beds contain layers of the siliceous concretions known as flints. Flints, how-
ever, are not restricted to the chalk, for, as already mentioned, they are to be
found in some of the limestone beds in the island of Antigua, though there do
not appear to be any in those of St. Croix.

All limestones are probably of organic origin, though this cannot be said
to be quite certain. Many that show no fossils when cursorily examined, are
found on further examination to contain them, while some limestones are full
of them ; for example, the encrinitc beds of the English carboniferous lime-
stone, beds which are crowded with the stems of feather-stars, something like
those which are occasionally brought up by our fishermen from the deepest
parts of the banks, or again the Purbeck limestone, which has originated in
fresh water and is full of the shells of fresh-water snails. Both these lime-
stones are compact enough to take a polish, arc consequently often used for
ornamental purposes, and are sometimes spoken of as marbles. That name,
however, ought properly to be applied only to those limestones which have
been so much altered by heat and pressure that their origin is completely
obscured ; such are, for example, the marbles of Greece and Italy. As already
mentioned, there do not appear to be any of these marbles or crystalline lime-
stones in St. Croix, although some are found in the neighbouring Virgin
Islands. In some parts of the world considerable beds of limestone are found
in which magnesia in considerable quantities, occasionally equal to nearly half
of the rock, is found. Such limestone is known as dolomite or magnesian lime-
stone, and is supposed to have been formed in inland seas by deposition, as
the result, in part at all events, of evaporation. It may, therefore, be classed
as partly a chemical deposit. The last limestone that need be mentioned here
is Oolite, or "roe-stone," a hmestone made up of tiny balls of carbonate of
lime all bound together as a firm rock, which, when broken through, presents
a surface resembling the roe of a fish.

Clay Rocks.
The indurated clays and slates of our island may in regard to their origin

88 THE BUILDING OF AN ISLAND.

all be classed as mud-stones, and they have their representatives all over the
world.

There are a few other important rocks which are not comparable with
anything found in our island. The principal of these is the carbon group, in-
cluding coal of various kinds, beds of mineral pitch, and graphite or black-lead,
which has been formed from coal by heat and pressure combined. The carbon
group has been produced from the vegetation of past ages, the plants having
obtained their carbon from the air and their mineral constituents from the soil,
and has, therefore, an organic origin. This is not the case with two other re-
markable rocks, salt and gypsum, both of which have originated as the result
of the evaporation of water containing these substances in solution, and must,
therefore, be classed as chemical deposits.

Enclosed or nearly enclosed seas that are surrounded by hot and rainless
countries naturallv tend to become Salter bv excess of evaporation; while the
water of the Baltic contains one and one-half per cent, of salt, and that of the
Atlantic three per cent., the Mediterranean contains five per cent, and the Red
Sea six per cent. If the channel which now connects the Red Sea with the
Indian Ocean should ever be closed bv the elevation of the surrounding land
and the Suez Isthmus be raised, the Red Sea would decrease in area and in-
crease in saltness until at last a great bed of salt would be deposited. The
same thing might happen with inland lakes in a country where the climate was
changing towards desert conditions. Beds of rock-salt are found in many
countries (the nearest to us in St. Croix being Santo Domingo), and it cannot
be doubted that they were formed in some such way as above suggested.

Gvpsum, which is a combination of lime and sulphuric acid, is likewise a
deposit from evaporation of inland water areas. It is often found in layers
near the beds of rock-salt ; the gvpsum beds in the neghbourhood of Paris,
from which the well-known plaster of paris is made, contain, however, fresh-
water shells, showing that the rock has been deposited in lakes, the water of
which was fresh when the molluscs lived in them.

There is another important set of rocks that has no true representative
here in St. Croix, namely, the sandstones. The sand from which these were
formed is entirely unlike the sand of our West Indian seas. As we learned,
in the beginning of our observations, our sand is of organic origin, being com-
posed of the remains of marine animals and plants, but the sand of the seashore
in manv countries is a purely mechanical product, being originally obtained, it
would appear, from granite and similar rocks in the wav described under the
remarks about granite in this chapter. The sandstones form immense beds in
Europe, North America and elsewhere, and are of such importance in some
parts that thev have given names to two of the English geological svstems, in
which they are abundant. The doubtfully stratified gneisses and the various
schists, which will be again referred to in the third section of this chapter, must
also be included in rocks not represented in St. Croix.

We may now leave the question of origin and consider

the buildinxr of an island. 89

2. — The Relative Ages of the Rocks.

While it is not possible to state the age of any geological formation in
definite time measures of any kind, it is possible to ascertain the order in which
the deposits have followed each other and thus to state their relative cigts. In
our own island we can see that the limestones and marls must be younger than
the indurated clays, because thev lie upon the clays ; and we can probably
extend this conclusion to apply throughout the east and west axis of the
West Indies; but how are we to get beyond that? In order to see how
geologists have been able to compare the ages of rocks in different countries
or different parts of the same country, it is necessary to consider a few facts
about fossils.

Fossils.

Fossils are the remains of living beings, whether animal or vegetable,
which have been preserved in the rocks. Generally it is the hard parts, such
as shell and corals, and the bones of animals, that have been preserved; but
occasionally the forms of the softer parts have been preserved likewise, the
forms of fishes, for example ; and insects, with forms and colours perfect, have
been kept for long ages embedded in tree gums, such as amber. The study
of the ancient Hfe revealed by fossils is known as Palasontology (meaning the
study of ancient beings), and it is one of vast extent. It shows us that, going
back in the history of the globe as recorded in the strata of its crust, we come
to a time when hardly anv of the species of plants and animals now living on
the earth had any existence, but the period had a life of its own; bevond that
again we come to another period, which, while containing some of the same
fossils as are found in the later period, is also marked by a special set of its
own ; and so on. But it may be asked how did the palaeontologists know
that thev were going hack in time? Suppose we ask a similar question about
our own island; how do we know that we are going baek in time when we pass
from the limestone formation to the clay formation ? Simply because we find
the clay formation belozu the limestones. The same reasoning applies to the
more extended study. Now it happens that England has afforded a particularly
good field for the investigation, for in that country the strata, though by no
means free from disturbances, yet lie over each other in a regular manner, the
lowest (oldest) being in the west and the others lying over them in succession
till we arrive at the highest (youngest) in the east. This succession has been
thoroughly studied by the English geologists, who have arranged the rocks in
systems, some of which have been named from the most characteristic of the
strata included in them, others from the parts of the world where they are
conspicuous, and others again (The Tertiary division) from the relative
abundance of their fossil remains belonging to species still living, These
systems are grouped into three divisions, the oldest rocks being classed
as Primary, the next as Secondary and the youngest set as Tertiary.
Some geologists add Quaternary, to include very recent rocks and others

90 THE BUILDING OF AN ISLAND.

in course of fcirmation, such, for instance, as the beach linmestones of our
West Indian islands.

The arrangement adopted by the English geologists has, with some modi-
fications, been very largely accepted by geologists in general.

The following table of the English systems is taken from Marr's Intro-
duction to Geology, explanations being here added after the names, as the
most concise way of giving them :

Systems.

f Recent (Quaternary of some authors)

I Pleistocene (Meaning most recent period)

Tertiary ] Pliocene (Meaning more recent period)

j Miocene ■ (Meaning less recent period)

L Eocene (Meaning Dawn of the recent period)

r Cretaceous (Chalk system) •

Secondary ; Jurassic (Named from the Jura Mountains)

L New Red Sandstone

r Carboniferous (Coal-bearing system)

I Devonian (From County Devon — Old Red Sandstone in North of England)

I Silurian (From the Silures, a British Tribe formerly occupying South Wales)

Primary ' Ordovician (From the Ordovices, a British Tribe formerly occupying Northwest
j Wales)

I Cambrian (Cambria = Wales)

L Precambrian (Before the Cambrian)

By way of further explanation, it may be added that the lower three
systems of the Tertiary division were named by the great English geologist,
Sir Charles Lvell, who called the lowest Eocene (dawn of the recent period)
because it was found that only 31^ per cent, of the fossil shells taken from it
belonged to existing species. The proportion of existing species increased
through the younger rocks, till in what Sir Charles called the Newer Pliocene
■all the shells belonged to existing species, the formation containing, however,
the bones of certain quadrupeds which had become extinct. Later geologists
have substituted the name Pleistocene for Newer Pliocene and have added
Oligocene as a system to come between Eocene and Miocene, the name im-
plying that the system contains the remains of a few recent species.

The reader who follows up the subject will find considerable difTerences in
naming the systems as well as the great divisions, and some differences also in
arrangement. Particularly he will find that the simple names of Primary,
Secondary and Tertiary have been replaced by names of life-periods ; and he
will find that the New Red Sandstone has been divided into Trias (so named
because including three different sets of strata) and Permian (so named from
the province of Perm in Russia, where it is conspicuous) and that the Trias
has been retained in the middle life-period, while the Permian is placed in the
ancient life-period.

The following is the arrangement adopted by the United States Geological
Survey :

the building of an island. 91

Period.

r Pleistocene
Cenozoic j Neocene (Pliocene

(Recent life-period) i (new recent) (Miocene

L Eocene, including Oligocene

Mesozoic < Cretaceous (Jurassic

(Middle life-period) ( Juratrias < Triassic

r- Carboniferous, including Permian
Palajozoic ] Devonian

Ancient life-period I Silurian, including Ordovician

L Cambrian

Algonkian
Archaean

It will be seen that the above (differs little from Dr. Marr's table. The
term Precambrian, though here replaced by part of the Archican (ancient) and
the Algonkian (from the territory of the Algonquin Indians) is still sometimes
used by the American geologists to include very ancient stratified rocks
without fossils, and rocks such as those gneisses the original stratification
of which is doubtful. The term "Recent" in Dr. Marr's table, omitted in
the above, appears to be unnecessary, as the name of a system, when we
have " Pleistocene."

It would far exceed the purpose of this chapter to try to describe, in how-
ever brief a fashion, the characteristic rocks and fossils of each of the above
systems. By way of illustration, however, we may take the English Carbon-
iferous system. As the name implies, it contains coal beds, but they are by
no means all of the system ; they form, indeed, a very small part of it. The
most conspicuous rock of the lower part of the system is the Mountain Lime-
stone, a hard blue-grey stone forming beds of two or three thousand feet in
total thickness, some of them containing mostly shells, some mainly corals,
others again full of stems of feather-stars (or sea-lilies), the encrinite limestone
mentioned in the preceding chapter. Some shales (hardened clays) are found
both above and below these limestones; then as we ascend, we come to great
beds of coarse sandstones known as Mill-stone Grit, having a total thickness
as great as that of the Mountain Limestone, and lastly we arrive at the set
called the Coal Measures. These "Coal Measures" are made up of an
immense thickness of shales and sandstones, clays and limestones, and contain
much concretionary iron ore, the coal beds themselves, though by far the most
important, forming only a small proportion of them. The coal beds, or seams,
as they are commonly called, vary in thickness from 20 feet or more down to
beds so thin as not to pay for the working. A coal bed commonly rests on a
bed of clay called the underclay and is often covered by a bed of dark shale
known as roofing shale. In the underclay the roots of the trees and smaller
plants from which the coal was formed can sometimes be seen, and occasionally
parts of the stems of the trees are found attached to the roots. These included

92 THE BUILDING OF AN ISLAND.

a few of the fir familv, but most of the trees, as well as the smaller plants,
belonged to the fern family and other flowerless plants. The shales which
cover the coal frequentl)^ contain fragments of the same plants mixed with
sea shells, which shows that the jungle in which the plants grew was over-
whelmed by an invasion of the sea, the result presumably of the sinking of the
land, a movement which must have taken place over and over again, with long
periods of rest between, before the numerous beds of coal and the many inter-
vening sandstones, clays and so on, of which the coal measures are made up,
could have been produced.

In all ages of the earth's history the outline of the shore, the different
depths in the adjoining sea, the courses of the great rivers, and the like, in
short the physical geography of the time and the region, must have had a
large share in determining the nature and extent of the respective deposits.
Hefice we find in the English Carboniferous system that its above named
three divisions are differently developed in the different coal-fields. In the
north the Mountain Limestones and the Mill-stone Grits are verv' largely
developed, in South Wales the Coal Measures, which there attain a thickness
of about I i,ooo feet. The separation into "fields " is the result of movements
which have taken place since the strata were deposited. The elevation of the
Pennine range, for instance, has brought the Mountain Limestone to the top,
the higher formations having been all swept away, but having been left on the
Avest of the chain to form the coal-fields of Cumberland and Lancashire, and
oii the east to form those of Northumberland, Durham and Yorkshire. The
above short sketch of the English Carboniferous system may serve to show
what is meant by a geological system; but it should be added that the English
coal-bearing strata, extensive as they are and important as they are to the
country's prosperity, are yet only a small part of the world's wealth in this
particular, for many extensive coal-fields are found in parts of Europe, North
America, India, China, Australia and South Africa, the North American fields
in particular being very large and far exceeding in area those of England.

In the Coal Measures the fossils naturallv belong mainly to the vegetable
kingdom, but there are also throughout the carboniferous system, as already
mentioned, many shells, corals and encrinites; there are also forminiferous
shells, insects, etc. Other systems are marked by special classes of fossils, for
example, the older rocks contain crablike creatures called trilobitcs, their shells
having ///r^^ lobes. The Old Red Sandstone of the north of England contains
many kinds of fossil fishes, while the rocks of Devon, belonging to the same
period, consist mainly of slates and limestones and contain numerous corals.
The Jurassic period is famous as the age of gigantic reptiles belonging to the
lizard family. There were snake-like lizards, flying lizards with bat-like wings
and fish-like lizards. The skeleton of one of these creatures now in the
Museum of Natural Historv in New York measures 60 feet in lensfth and 11
feet in height. In the time of the deposition of the Oolitic limestones, which
form part of this system, there were also numerous sea creatures resembling

THE BUILDING OF AN ISLAND. 93

the nautilus in form, the shells of which arc known as Ammonites. Some of
these ammonites are of large size, and the writer remembers seeing near Port-
land, in Dorsetshire, manv of them used along with the slabs of Oolite lime-
stone to form stone fences between the fields.

The lower beds of the cretaceous system are not chalk, but sands and
clays, and their fossils have considerable resemblance to those of the Jurassic
period. The chalk beds themselves contain numerous shells and sea-eggs, but
are chiefly characterized by being formed largely of foraminiferous shells and
their fragments. The flints, which lie in sheets in the chalk and show as
dotted lines in the cliffs, are concretions of silica, the source of which has been
the silica extracted by marine creatures, such as sponges, from sea-water.
This may be illustrated by the sponges of the present day, many of which
contain flinty spikes such as may sometimes be seen in the sand from the sea
bottom, say, for example, in Christiansted Harbour.

The fossils of the Tertiary Period show us the gradual approach to the
life of the globe as it now exists — through numerous remains of both land
and sea creatures and various plants. The appearance of man on the earth is
a recent event, speaking in geological terms, but a very ancient one if we use
the language of human history.

The above remarks may perhaps serve to give some faint idea of the great
extent of the study opened up by the fossils which the various strata of the
earth's crust have yielded and continue to yield; a study, the difficulty of which
is increased by the many breaks that must necessarily come in the record and
by the necessity of considering the climate and other conditions, not only of
the various periods, but of the difl^erent places to which the fossils respectively
belong. But we must now return to the main purpose of this section, namely,
to answer the question, what are the ages of the rocks of St. Croix in relation
to those of the earth's crust in general, where must our formations be entered
in such tables as have been quoted ? The answer must be left to the geologists,
and we find that Professor Cleve, judging from the fossils collected here and
in the neighbouring islands, puts down our Marl and Limestone Formation as
of Miocene age and our Bluebeach Formation as Cretaceous ; from which it will
be seen that, notwithstanding the great periods of time that must have passed
during the deposition, the subsequent movements and the sculpturing of our
St Croix formations, thev are comparatively young in the world's geological
history, and we begin to have a dim perception of what a grand and marvellous
work the creation of this earth of ours has been.

3. — History of the Rocks Subsequent to their Origin.

xA.!! the various changes in the character of the rocks which we found to
have taken place in St. Croix, such as hardening, jointing, cleavage, formation
of concretions, alteration by heat, and so on, are known among rocks else-
where ; but all rocks have not been submitted to these changes, a striking ex-
ample of which is found in the London Clay, a deposit of about 500 feet in

94 THE BUILDING OF AN ISLAND.

thickness, above which, on some overlying gravels and clays, the citv of Lon-
don stands ; this great deposit has remained a mere stiff clav, not entirely free,
however, from changes, for layers of concretionary blocks of hydraulic lime-
stone, the blocks known as septaria, have been formed in it.

The term " metamorphism " (change of form) is used to indicate all im-
portant changes that have taken place in rocks since their deposition ; but the
name metamorphic rocks is commonly restricted to clay-slates, marbles, gneiss,
schists and other rocks that have been laid down as sediments and subse-
quently altered by heat. Some of these, as already noted, we have in the
Danish West Indian Islands; others are not represented here. 6";/m.f, already
mentioned under igneous rocks, is a very abundant rock, consisting of the
same crystals as granite, "but the materials showing signs of a stratified arrange-
ment. In some masses of gneiss the tendencv is so sliijht that ceolosfists have
supposed this peculiar arrangement to have resulted, like the cleavage in slates,
from pressure ; in other cases the linear arrangement is so conspicuous that
the rock has been supposed to have been originally a stratified deposit from
granite, which has been subsequently altered and hardened by heat. The
Schists are rocks dividing naturally into irregular layers (the division is implied
by the name) and are apparently altered sedimentarv deposits derived from
granite rocks. Shales are hardened muds, frequently showing a similar tend-
ency to division.

In all parts of the world the sedimentary rocks are found to have under-
gone similar upliftings, bendings, denudations and depressions as we find re-
corded in the rocks of St. Croix. Even the summits of the highest mountains
frequently show stratified rocks, just as do those of the lower hills and the
plains. Evidence has been adduced to show that the lifting and lowering of
certain parts of the earth have gone on, as in the geological past so also in
historic times. Earthquakes, even in the present day, are sometimes attended
with changes in the level of a country, and are probably the effects of such
changes. This has been particularly the case with the shores of the South
American countries bordering the Pacific ; but the most striking illustration
which the present writer has met with is recorded in the June number (1907)
of the '• Outlook," in an article headed "An Alaskan Wonderplace," by Oscar
von Engeln. Here, the traveller tells of the grand mountains and glaciers in
the vicinitv of Yukutat Bay, and after describing the way in which a great
glacier grinds down the rocks over which it passes, and how the material it re-
moves is carried off by the stream issuing from beneath the foot of the
glacier and by it is spread out over the adjoining i)lain, he continues thus:

."If the efforts which the glacial streams are making to counteract the
destructive erosion of the ice are termed herculean, then titanic must be the
word applied to the force which, in a single upthrust, lifted the land surface
around Yukutat Bay, mountains and all, forty feet higher above the sea level
than they had been previously. Never before in the historv of geological
science has a recent u])lifl nf such magnitude been recorded. Moreover, tlie

THE BUILDING OF AN ISLAND. 95

evidence regarding the lesser ones is very obscure, so that we have here our
first direct knowledge of tremendous crustal movements.

"The whole uplift took place during the latter half of September, 1899,
being practically continuous during that time, with occasional sharp shocks;
it caused great waves in the bay, probably as the water rushed out from it, for
its bottom also was raised, as is proven by the appearance of new reefs and
islands in its confines. Today one may walk for miles along its shores, over
dry beaches, high above the reach of the highest storm wave, crunching under
foot the yet undecomposed seaweed and the whitened barnacles clinging still
to the rocks on which they once grew, and around which the surf once rolled
continuously. The evidence of the uplift is complete. Old sea caves and
wave-cut cliffs, areas where the plants have not yet had time to gain a foothold,
all help to tell the story. If one has wondered how the sediments of old sea
bottoms may form the summits of the highest mountains, here is an illustra-
tion of a force at work adequate to lift them to such a height.

" The two weeks during which this uplift occurred was a period of almost
uninterrupted earthquakes in the Yukutat Bay vicinity. As reported by the
missionary at the Indian Settlement at the mouth of the bay, and by prospectors
encamped near by, some of the shocks were of great violence."

To the evidence of such examples may be added that of the raised beaches
found in several parts of the world, which show that elevations have taken
place in quite recent geological times.

The raised beaches of Norway are well-known examples, and a recent
writer has given an account of several such beaches near Taltal, in the north
of Chili, where he found three very distinct levels, namely, at fifteen feet, eightv
feet and two hundred feet, respectively, above the present sea level, which
were marked bv the presence of boulders, well-preserved sea-shells, and caves
of wave-erosion, pointing evidently to three successive upliftings of the coast
at the place named.

We must remember, too, that an elevation sufficient to balance the wearing
down of an island might take place without its being possible to observe it.
Geological processes are for the most part extremely slow, we have seen that
four centuries would probably be required to lower St. Croix by a single inch ;
where would the means be found to measure a rise of an inch at the end of
that time, should it have taken place ? If it were two inches, there would be
a balance in favour of the island ; it would be rising, but how could that be
discovered ?

The earlier geologists supposed that the processes by which the earth's
crust has been built up had been formerly very active, but had in the present
day nearly ceased. Sir Charles Lyell, in his " Principles of Geology," by
calling attention to the nature of geological processes and by pointing out
similar changes that are taking place at the present time, showed that this view
was erroneous, but he probably went too far in the opposite direction in con-
cluding that the story had been always the same since the dawn of geological

g6 THE BUILDING OF AN ISLAND.

histor}'. It is now generally admitted as probable, that the earth has cooled
down from a molten state and that the crust has been pushed up in undula-
tions here and there as the result of the contraction of the elobe durine its
cooling, a contraction which, it is maintained, is still in progress. If this view
is accepted, it seems necessary to admit that the earlier processes may have
been very different, at all events in degree, from anything we now see.

On the other hand, it is quite certain that the greater part of the geological
phenomena of the past may, as in the cases just quoted, be illustrated by the
changes which we see to be taking place in our own dav.

Age of the West Indian Volcanic Chain.

We may now return to the question which was left over from the last
chapter, namely, the relation as to age between the two great axes of the West
Indies.

For clearing up this question we must again look to the geologists. Prof.
Cleve writes of a limestone deposit in St. Kitts as follows:

"At the foot of Mount Misery there is in Brimstone Hill a white lime-
stone rock of considerable size, surrounded in all directions by loose volcanic
rocks. I have not seen in it any trace of stratification. The rock has the
appearance of chalk and contains many fossil shells and corals, the greater
number in the form of casts. I have found about 43 different mollusca, all
of species still living in the Caribbean Sea, except a single specimen of a
Modiolaria closely related to a northern still living species. Among the fossil
shells one of the most common is Tcllina Grjineri Phil., also occurring in
the miocene strata of Cuba and Porto Rico, and still living in the Caribbean
Sea, but very rare. The greater number of still living species indicates the
recent time at which the deposit was formed, and the formation may probably
be determined as the newest pliocene or post-pliocene."

In the volcanic island of Basseteree, Guadaloupe, Professor Cleve says,
some fossiliferous deposits have been found by Mr. Payen. " One of these
deposits occurs at the height of 40 meters, about 50 meters from the shore, and
the other, which rests upon horizontal beds of volcanic rocks, reaches the
height of 100 meters and is 200 meters from the sea. They seem to belong
to the same geological time as Brimstone Hill in St. Kitts."

The same geologist further writes of St. Eustatius : ' According to Maclure
there is on the southeast slope of the cone a lime deposit of corals and shells,
'similar to those found in the sea." He (Maclure) gives the following descrip-
tion: 'The whole of this marine deposition dips to the southwest at an angle
of upwards of 45 degrees from the horizon, resting upon a bed of cinders, full
of pumice and other volcanic rocks, and is immediatelv covered by a bed of
madrepore, sand and cinders mixed together, with blocks of volcanic rocks so
disseminated that there can be no doubt of the volcanic origin of the sub-
stance above and below the madrepore rock.' "

THE BUILDING OF AN ISLAND. 97

From the above quotations it is evidcMit lluit the limestone rocks men-
tioned as so closely associated with the volcanoes have been put down at least
during the eruptions, if not earlier, yet the evidence of the embedded fossils
shows them to be "post-pliocene"; from which it may be inferred that the
West Indian volcanoes are quite young in the world's geological history, and
much younger than the formations which make up the east and west axis 'of
these islands.

Questions of geological age must be left to the Palaeontologists, yet it may
be here pointed out that there must have been land along the north and south
axis long before the existence of the present volcanoes. Dr. J. W. Spencer,
who has of late paid a great deal of attention to the geology of the West
Indian Islands, has concluded that in the volcanic islands, as well as in Antisfua,
there is an ancient base of trap rock, which he speaks of as "pre-tertiary trap."
In Antigua it is between this trap, exposed along the southwest coast, and the
limestones of the northeast that the strata containing silicificd fresh water shells
and silicified woods occur. The wood fossils prove that there must have been
land there at the time they were deposited, and it was this land which after-
wards sank under the sea and received upon it the limestone beds of the north-
east. In Barbadoes also evidence is found of an ancient land. The geology
of that island was described by Sir Robert Schomburgh in his History of Bar-
badoes, published in 1848, and it has been more fully described a few years
ago by the well-known English geologist Jukes-Browne and Professor Harrison.
The larger part of the island is covered with a coral formation, all of which
the latter writers consider to be very recent. Dr. J. W. Spencer believes, how-
ever, that there are remains of an older limestone formation than the recent
coral rocks. However this may be, the whole mass of limestones rests on an
older formation, which has been reached bv borings through the limestone in
several places, and which appears on the surface over a considerable area on
the east coast, an area which has been so variously carved out bv the streams
into hill and dale that it is locally known as Scotland. The " Scotland forma-
tion " consists mainly of a great thickness of sands and sandy elavs, some of
them hardened into stone, others having very little coherence. Sir Robert
Schomburgh calls attention to the shore sand in that district, pointing out that
it is quite unlike the sand on other parts of the coast, being siliceous while the
other is shelly; it is, in fact, the kind of sand which is mentioned in Part i of
this chapter as derived ultimately from granite. Over the " Scotland forma-
tion " is another coming between it and the coral limestone, and known as the
" Oceanic formation." Mr. Jukes-Browne and Professor Harrison give a full
account of this remarkable formation, which is made up of over 300 feet of
deep-sea deposits, some of the layers being chalky and abounding in foraminif-
erous shells, others consisting of fine clays of varying colours and siliceous
earth, the latter, with a thickness of 130 feet, being almost entirely composed
of the microscopic flinty skeletons (whole and fragmentary) of creatures
known as Radiolaria, and hence called Radiolarian earth, or, on account of its

g8 THE BUILDING OF AN ISLAND.

fineness, Radiolarian ooze. The Radiolaria are near cousins of the Foraminif-
era, but their coverings are not made from lime, like those of the latter, but
from the clearest silex; and when they are seen through the microscope, this
quality, along with their greatly varied and beautiful forms, make them very
attractive objects. The Radiolarian shells of the present day are found in
water 10,000 feet or more in depth ; hence it has been argued that the Scotland
beds, which belonged to shallow seas, must have sunk to at least that depth.
How long did they remain there to take the considerable thickness of those
fine-orained beds on their surface? It is impossible to answer, but when we
think of the fine rain of these microscopic skeletons descending on the ocean
floor, we must conclude that an immense time must have elapsed before it
could have produced such a thickness of strata as the later elevation has made
visible. The Scotland beds contain a substance which Sir Robert Schomburgh
describes as coal. Mr. Jukes-Browne speaks only of the " black bituminous
clays " of the Scotland formation. Locally the product is known as vianjack.
Petroleum is obtained from the same formation. The presence of such beds,
however they may be described, is sufficient to prove the existence of an
abundant vegetation in that ancient land, just as the agatized woods prove it
for Antigua.

Dr. Spencer says that the age of the Scotland beds has not been settled,
but he thinks from their very great total thickness that they must be dated
probably as far back as the Eocene time. It is worth noting that these beds
were very much disturbed before they went down into the sea, for they dip in
various ways at different places, yet were planed down before sinking, so that
the " oceanic beds" rest upon their upturned edges, or, in geological language,
they rest unconformably upon them. The uppermost bed of the oceanic series
is a twenty-five feet of thickness of " grey volcanic mudstones," which the
authors consider to have been probably formed from volcanic dust drifted from
distant volcanoes, as there is no sign of any volcanic outburst on Barbadoes.
It is interesting to note that radiolarian earth is also found in Trinidad, Cuba,
Hayti and Jamaica.

From the above facts and expert opinions it seems likely that there was
an old north and south axis long before the present volcanoes existed, and pos-
sibly as old as our east and west axis.

While the settlement of questions of age must be left, as already said, to
the pakeontologists, the geological facts available are very instructive, for we
see that these other islands have, like our own, accumulated the materials of
their construction from different sources, and have been subjected to elevations
and depressions similar to those which we have seen to have taken place in our
own island.

THE BUILDING OF AN ISLAND. 99

CHAPTER XII.

Conclusion.

While it seems desirable, in entering on the study of the geological forma-
tions of our island, to begin with the younger set of rocks and trace the story
backwards, it may be instructive, in summarizing the results of our observa-
tions, to take the opposite course, and, as far as possible, note the leading
events and conditions in their natural sequence.

As a preliminary, we must remember that the crystalline structure
prevalent in our older formation has been induced in the strata since the
materials of which they are composed were deposited, and similarly that
the dykes of igneous rock which we find cutting them through have been
intruded, so that in the first instance we have to confine our thoughts simply
to their deposition.

To begin with, we have, then, to picture to ourselves as existing here long
ages ago, perhaps about the time that the chalk of Europe was being deposited,
a sea bottom to receive the beds and an adjacent land from which the material
to form them was obtained. That the land was near by is shown by the
occurrence of conglomerates, and in a striking way by the layer of well water-
worn pebbles previously mentioned as seen in Buck Island, a layer which must
either have formed a part of a shinglv beach or have been put down in shallow
water not far from it. The proximity of the land for at least the greater part
of the time during which the materials were being deposited, is further shown
by the frequency of the occurrence of ribbon-like markings in the stone,
markings which indicate successive deposits of thin layers and point to oft
repeated invasions of sediment from the shore, and it is also shown by the very
numerous beds that have reached thicknesses of a few inches only and may
well have been put down not far from the land. The thick beds of fine-
grained slate, such as those we see near Mt. Victory, must have been formed
farther out, in places to which the currents could bear the finest drift only;
yet a distance of one or two miles would, in most cases, be sufficient to secure
the needful conditions, though it may, of course, have been very much
greater.

The conception of another land still farther back in time, a land which we
have pictured as being destroyed in the making of the older portion of our
island, arouses our interest. What sort of a land was it? We see in our own
rocks part at least of the stuff of which it was built, and we perceive that it
had a sea beach, in some parts bordering shallow seas, and it had streams that
ran down from its hills and valleys and across its plains. Was it a volcanic
land? The finding in the strata of St. Thomas of scoriaceous fragments, as
described by Prof. Cleve, proves that it was, and it may be that the volcanoes
furnished a eood deal of the material from which our rocks were formed. On
the other hand, the volcanic outbursts may have taken place through non-
volcanic strata, and the latter may have supplied the greater part of the

lOO . THE BUILDING OF AN ISLAND.

material in question. At all events, the strata we now have were laid down
at the sea bottom, and they reached a thickness so great that we must suppose
that the land from which they were being formed was sinking while the accu-
mulation was in progress.

What depth of material was lodged in that ancient sea? If we could get
anv reliable ajiproximation to the total thickness of the beds in the older
formation, as we can do for the marl and limestone formation, it would be easy
to answer the question, so far, at least, as regards the part now remaining; but
we do not see the base on which the rocks rest, and the strata, as we have
seen, have been very much disturbed. Professor Cleve, writing of St. Thomas,
says: "The blue-beach seems to me to be at least 2,000 metres (about 6,500
feet) thick." This probably excludes the felsite of the south and the clay-
slates of the north, and if so the total thickness of the St. Thomas strata would
presumably be much greater than that stated. If in St. Croix we take the
distance between Lower Concordia and Mount Washington, across the southern
side of the northwestern anticlinal and assume a high angle of dip throughout,
we should get a thickness of at least 12,000 feet; but on the one hand we
cannot be sure that at Concordia we have arrived at the southern limit of the
southerly dipping beds, neither do we know the depth to which the strata
reach at the axis of the anticlinal, and on the other hand we cannot be sure of
the absence of minor folds, the presence of which might considerably reduce
the estimate. It seems, however, to be safe to conclude that the total thick-
ness of the clay formation is very great and is to be reckoned by thousands of
feet instead of bv hundreds as in the limestone formation. While this great
mass of clays was being piled up, the sea added on its own account occasional
small contributions of limestone.

After the deposition of the great thickness of clays and its few associated
limestones, the accumulated beds were forced up above the sea and compressed
into the numerous parallel ridges and hollows which we have found them now
to reveal, and this process probably extended through a very long period of
time. Other processes, most likely at the same time, and perhaps from the
same causes, went on, the strata being to a great extent made crystalline and
otherwise altered to the forms in which we now see them. Dvkes and masses
of igneous rocks were, probably about the same time, forced into them ; but
that this invasion of molten matter ever went so far as to produce eruptions
ending in the formation of volcanoes there appears to be no evidence to show.

Thus a new land was formed out of the waste of the old ; but no sooner
was it pushed above the sea level than the sea began to attack its edges, and
the atmosphere and the rains began to lower its surface ; and continuing
through long ages, these forces wore down the slopes of its ridges, first into
hill and dale, and then, in part at least, into plains, just as they had done with
the ancestral land.

Then comes another swing of the pendulum, the worn down land begins
to subside, and on its plains, now under the sea, great thicknesses of sea sand,

THE BUILDING OF AN ISLAND. lOI

with corals and other remains of sea creatures, are slowly accumulated, while
occasional deposits are brought down b}' streams from the remainder of the
land not yet under the water and are mingled with the shell sand or are laid
down as small beds of hard sand and gravel. Whether the whole of the land
ultimately went down under the water there is no means of ascertaining;
neither is it possible to say to what depth it sank. Down to the present time
no oceanic deposits, as in the case of Barbadoes, have been discovered in St.
Croix, and indeed it seems likely, from the frequent occurrence of pebbles
from the older rocks in the marl formation, that the latter was put down
during a period of slow subsidence. It does not seem likely, therefore, that
an oceanic deposit, if it existed here at all, would be found, as in Barbadoes,
between the limestones and the older rocks. However that may be, the sub-
sidence must have been a long one to allow of the deposition of the 600 feet
of limestones and marls which we now see, to say nothing of that large part of
the original deposit which must have since been swept away.

After the long interval of subsidence comes another period of lifting
when the remnants of the second land, bearing on its surface the great accu-
mulation of limestones, is once more forced above the waves, this time, how-
ever, with much less disturbance of its strata than in the older uplifting move-
ment, and without intrusions of molten rock, or at all events with none that
were powerful enough to penetrate the limestones. Just as we asked in regard
to the sinking of the land, how deep it went under the ocean, so we may now
ask about the lifting, how high the land was raised. In an earlier chapter it
was mentioned that naturalists had concluded from the plants and land-shells
of the West Indian islands that they had at one time formed continuous land,
in which case the lift we are considering was probably very great. Dr. W. J.
Spencer, the American geologist already quoted, has arrived at the same con-
clusion on geological grounds. He says that the soundings off the coasts of
the Atlantic States show that the courses of the rivers flowing from the
mountains over the present coast plain, can be traced over the sea bottom far
out into the ocean to depths of thousands of feet, from which he concludes
that the land ofT the coast is a sunken plain, and he sees reason to believe that
the sinkinsf has extended through the Bahamas and the Caribbean Islands to
the South American coast. He believes that there is evidence to show that
there was a large plateau joining the two continents and having its highest line
towards the east while its drainage ran west into the Caribbean Sea. Hence
he regards the channels between the islands as former valleys, and the islands
themselves as remnants of a mountain chain which had been intersected by
the streams. He writes of " The West Indian bridge between North and
South America" and speaks of the present great depth of the channels as a
"yardstick" to measure the former heights of the mountains, which he
estimates to have been 10,000 to 12,000 feet or perhaps in some cases even
14,000 feet. These great elevations he believes were reached in Pliocene
times, after a previous sinking of the land subsequent to the deposition of the

I02 THE BUILDING OF AN ISLAND.

Miocene limestones. Dr. Spencer regards tliese great earth movements as
quite different from the mountain-building thrusts, and if his views are correct,
it is likely that the land here stood much higher at the end of the period of
lifting than we now see it.

Whether this were so or not, we see a third land appear to view, not to
remain intact, however, but to be dealt with just as its predecessorShad been
dealt with, that is to say, to have its I'aw material broken up by the air and
sculptured bv the streams into beautiful forms, and its soil prepared and kept
fit for the nourishment of the multitude of plants that come to adorn its
surface. On this land it is that we live, and most of us feel that it is indeed
a fair and a pleasant land.

Some years ago, the writer, while driving along one of our country roads
with a young companion, pointed out a few layers of limestone showing in the
roadside bank, and remarked that we could there find a lesson about the way
in which the island had been built up. " But I thought the world was as God
made it," was the reply, to which was answered, " Certainly, you can still think
so, but that need not prevent your learning something of the way in which it
was made." Fortunately, no special knowledge is needed to see that in this
beautiful island of St. Croix we have a goodly heritage, and to feel the grati-
tude that naturally arises from the sense of the greatness of the gift. For
some of us the ground for gratitude is greatly increased by the added pleasure
of knowing something, in however meagre and dim a fashion, of the truly
wonderful processes by which this goodly heritage of ours has been created.

THE BUILDING OF AN ISLAND.

103

NOTES.

On Finding the Anticlinal Axis of the Northwest.

It has been noted (page 45) that an anticlinal
axis divides the rocks of the Northwestern Hills
which dip to the south or thereabout from the rocks
that dip to east-northeast or thereabout, and that
such axis is found to lie about west-northwest and
east-southeast.

In order to be able to lay down this line we
must traverse the roads passing through the hills
and note the dip of the stratified rocks wherever
we can find them.

In this examination it will be advisable to com-
mence with the road passing from the estate Little
La Grange, in the valley, to the estate Puneh on
the top of the hill.

The diagram shows the sequence of the differ-
ent dips met with along this road. The measure-
ments between the successive points are not exact,
having merely been stepped out ; but they may be
of some use to a reader who may care to follow up
the observations. It may, in the first place, be
noted that near Punch the southerly dips that have
been met with during the ascent change over to
northeast. Next we may note that at several
points the strata are vertical or nearly so, while
at other points they pass over to northerly dips.
This need not confuse us, for we have already
learned that rocks, which on the whole dip to the
south, may in some places be vertical and in others
be even pushed over so as to get a reversed dip.
The great value of the observation in this case is
that it enables us, when we pass to the seashore,
to see that we may properly retain small areas of
northerly dip in the large area of southerly dips,
seeing in the rocks of such smaller areas examples
of reversion of dip on a considerable scale, and
not change from one larger area to another.

Following the coast from Frederiksted north-
wards we first come to the cliff at Spratt Hall,
where we find slaty rocks in regular layers dipping
to north at about 50. This is so great an amount
of reversion that we might be inclined to think
that we must have come to the north slope of the
anticlinal if we did not observe that the dip lacks
the more marked easterly tendency which we find
farther on when we actually come to the great
northeast slope of the anticlinal. At Butler's Bay,
farther north along the shore, we find a like dip
as to direction ; but the rocks have not been thrust
so far over, the dip being 75 degrees to north-by-
east. Continuing northward, we come to the real
change when we arrive at the estate Northside,
where we find in a cutting a dip of from 30 to 40
degrees to east-by-north. Our having now passed
into the area of the northeast dips is confirmed
when we come into Ham's Bay, where we meet

ir^.i^

:^0

104

THE BUILDING OF AN ISLAND.

with a dip to northeast at about 50 degrees, while
at the Bluff we find highly contorted strata, the dip
varying greatly, but being on the average to a lit-
tle south of east. So far, then, we have discovered
that the dividing line berween the two sets of dips
mu.st begin on the coast, between the e.statp But-
ler's Bay and the estate North Side, and must
also pass just to the south of the buildings at the
estate Puiuli. To fill up the interval as far as
po.ssihle. we traverse the road from the estate
Sprat Hall up the valley known as the Creque's
to the estate Mt. Viitory. On the estate Sprat
Hall (the mill-tower lying north-northwest) we
find thin beds of indurated clay rocks exposed,
some of them decomposing to a white clay, the dip
being about 70 or 80 degrees to north by- east.
After this the debris brought down by the stream
which runs along the bottom of the valley, hides
the rocks until we come nearly under Mt. Wa.sh-
ington, where we find exposures of layers of in-
durated clay and slaty rocks, with dips varying in
direction from east to east-northeast, and in
amount from about 40 to 50 degrees.

Hence it appears that we have again crossed
the line of divi.sion or, in other words, the anticlinal
axis, and just in the place where our previous ob-
.servations had led us to expect it. Continuing
along the same line of road eastwards we find re-
peated evidence that we are traversing the area of
northeasterly dips. At the small waterfall, on the
way up the valley, we find the dip east-by-north
at 35 to 40 degrees. The rocks are mostly slates,
some of them thin -bedded and others two feet or
more in thickness. The cleavage appears to lie
about northwest and southeast. Farther on. near
Mt. Victory, slaty beds are shown, dipping to east-
northea.st at about 45 degrees. Crossing Annaly
Hill, at the top of which, near the mill, there are
evidences of strata dipping about east, we come,
near its foot, to slaty rocks in slabs with a dip of
about 25 degrees to north-northeast, which is ex-
ceptionally far round to the north and appears to
be only a local departure from the usual direction,
for a little farther on, where the road coming down
from Annaly joins the road to Montpellier, we find
a large gravel pit showing dips at about 30 or 40
degrees to east-northeast. Following the road
past Montpellier, we find at Two Friends hill
layers of slaty rocks dipping to east-northeast at
about 45 degrees

Lower down the valley (near the old mill at
Springfield; there are several exhibitions of the
rocks by the roadside, mostly slaty, with a rough

cleavage about northwest and southeast, the dip
being east-northeast at about 50 degrees. Lastly,
in the natural cut made in the steep hillside by the
stream northwest of Grove place there are traces
of stratification, the dip being east-by- north at
about 45 degrees.

After emerging at Grove Place into the great
plain, the observations cannot be continued to the
southeast, the whole plain being covered by debris
from the hills, but they can be continued eastwards
in the hill at Upper Love village, where two gravel
pits reveal the stratification, that on the west side
showing a few strata dipping east at about 70 de-
grees, that on the east side showing a like dip at
about 60 degrees.

We may further amplify our observations by
now returning to the western side of the hilly dis-
trict of the Northwest and traversing the road that
leads past the estates Prosperity, Jolly Hill, and
Orange Grove, and then enters the road just ex-
amined. Here we find a beautiful exhibition of
the rocks of the district where, at Jolly Hill, the
stream crosses the road and runs over a set of in-
tensely hard blue-beach rocks, in which the strata
are clearly marked. The dip here is south-south-
east at a very high angle (about 70 degrees) Far-
ther along the road, before reaching Orange Grove
village, we find, in a road cutting against the hill-
side, stratified rocks dipping to northeast at about
45 degrees. Here again it is-plain that we have
passed out of the area of southerly dips into the
area of northeasterly dips ; in other words, we
have once more passed the anticlinal axis, which
consequently we are now able to continue from
near Punch to a point in the road between Jolly
Hill and Orange Grove.

To establish the fact that the southern dips pre-
vail through the southwestern part of the North-
west Hills (just as we have shown that northeast
dips prevail through the northeastern part), we
can add to the observations already made by
following the roads leading from the southern
plain up the several valleys which come down the
south slope of the hills. There are three such
roads, the middle one showing on the edge of the
stream some plainly stratified rocks dipping to a
little east of south at a high angle and to the south
of that another outcrop on the east side of the road
showing a high dip to north. A careful search in
the other two valleys would perhaps give similar
evidence, though such has not been seen by the
pre.sent writer.

THE BUILDING OF AN ISLAND. IO5

NOTES.

On Finding the Anticlinal and Synclinal Axes of the Eastern Triangle.

On page 49 it was shown that on examining the
rocks along the cleft called "Spring Gut," which
cuts through the Christiansted group of hills from
North to South, a change in the dip was found to
take place towards the southern end of the valley
where the dip passes from about southwest to east-
by-north, and that at Longford, in the plain be-
low, the dip was found to be east-northeast. First
assuming that we have here, at the change of dip,
a point in a synclinal axis, and that such axis has
the same direction as the similar axis in the north-
western oblong, we run out the line, in both direc-
tions, and we shall find that, with a very slight
modification, it will, in both directions, come out
at places where the dip changes from the one class
to the other ; that is to say, from dips looking
towards the south quadrant to dips looking towards
the northeast quadrant. Towards the northwest,
along the line, the change takes place close to Bees-
ton Hill, where the main road some years ago
showed a section roughly sketched in the diagram
(Fig. 32). When this diagram was drawn and the
following notes made, the writer had no idea of the
true significance of the change of dip at this place,
but supposed it be merely a local reversion. It was
not till long afterwards that he found that the new
dip extended over a considerable .strip of country
.southwards and indicated the presence of a syncli-
nal axis at the place where the change takes place.
The notes read thus ; "In repairing the road at
■ a ' and ' b ' in the plan the bank has been cut in-
to by the hoe and a clean surface exposed at about
six feet below the surface of the soil at the top of
the bank. The cut surface shows the usual thin
bandsof indurated clay rocks, some of dark colour,
but most of various light brown shades. At ' a '
they dip south, at 'b' north. The decomposition
is such that the greater part may be called clay,
but some beds, though cracked into small frag-
ments, retain a certain degree of hardness in those

fragments. The whole length has been quite
smoothly cut with the hoe. On the opposite side
of the road the rock also shows strata dipping
northwards."

Later observation showed that the " north-
ward " dip was about north-northeast, or north-
by-east, and, as already noted, such dips extend
over a wide strip of country .stretching south-
wards.

While on the south side of this change at Bees-
ton Hill the dips areall to the north, on the other,
namely, towards Christiansted, they are all to
southwest. Hence it is clear we have here come
upon a synclinal axis, and it is the same as was
iddicated by the change of dip in the "Spring
Gut" Valley.

Returning now to the middle of our synclinal
line and following it to the southeast we find that
it separates the rocks at Fareham Point, which
dip to northeast, from those at Petronella, which
dip to southeast-by-south. Thus the northern
boundary of the strip of country where the
strata have a northeasterly dip is apparently set-
tled. Proceeding next to find its southern bound-
ary, we first follow the south coast from Fareham
westwards to find out where the dip changes ; and
we find south of the old mill at Fareham some
stratified rocks of indurated clay dipping east-
northeast at about 50 degrees. Hence we are still
in the same strip of northeasterly dipping rocks.
Farther west, however, we come, on reaching the
point at the east end of Springs Bay, to a set of
clearly stratified indurated clay rocks dipping in
quite a dilTerent direction, namely, to south-by-
east, at about 45 degrees. Hence we appear to
have passed once more into a district of southerly
dips. This discovery is borne out when we follow
the road from Longford westwards and find close
to the new bridge at Cornhill some well-defined
strata dipping at about 60 degrees to south-south-

FiG. 32.

io6

THE BUILDING OF AN ISLAND.

west. Hence we see that the line separating the
northeast dips from the southern dips passes from
east of Springs Point, just south of Longford and
north of Cornhill Bridge. We are able to continue
it still farther to the northwest by noting that an
old quarry (gravel pit) on the main road going
south past Catherine's Rest (Longford's new
chimney lies southeast-by-east) shows rock layers
with a distinct dip to south-southwest at about 45
degrees, while another gravel pit to the north of
that, namely, at the turning in the road, shows
traces of a dip to north-northeast at about 30 de-
grees We can therefore continue the line north-
west, passing between the.se two quarries.

Thus we have traced out a line which separates
northeastern dips from southern dips, and we find
the result confirmed by the dips at Waiter's Point
and a point to the east of it. At the latter point it
is true that two dips are found, some of the rocks
dipping to northeast-by-east, some southwest-by-
west, the alternations taking place within an in-
terval of only a few yards. These changes to
northeast appear, however, to be mere reversions
of the dip, which all the facts show should be count-
ed with the .south quadrant class. Hence we have
laid down a line separating the areas of different
dips, and this line is of course an anticlinal axis,
just as the line to the north of it is a synclinalaxi?,.

When we now go back a little in our story, and
compare the dips on either side of the above traced
anticlinal axis, the first which we have discovered
in the eastern triangle, with those ou either side
of the anticlinal axis of the Western Oblong, we
notice that while an examination of the southeast
part of the line, say from Longford to the shore,
shows us that the dips bear a similar relation to
the present axis as do those of the Northwest anti-
clinal to their axis, that is to say, they have on
both sides an inclination to the east, an examina-
tion of the other part, that is the northwest part,
of the line, shows dips tending rather in the other
direction, namely, north-northeast or even north-
by-east on the north side of the anticlinal and
south-southwest or even southwest on the south
side. Compare, for example, the pair of dips at
Longford and Springs or Fareham and Springs,
towards the southeast end, with the pair at Bugby
Hole and Corn Hill bridge or Catherine's Rest and
Waiter's Point towards the northwest end of the
line.

If now the tendency to the east on either side
of the southeastern part of the anticlinal is caused,
as suggested in regard to a like arrangement in
the Western Oblong, by a cross elevation tilting
the rocks towards the east, may not the opposite
be the case in the northwest part of the anticlinal ?
In other words, may there not be a cross axis of
elevation which separates these two diverging ten-
dencies, tilting the rocks on its east side towards
the east and on its west side towards the west?
And if so, where is this axis? It may not be pos-
sible to lay it down with any exactness ; but when

we see that the rocks in Christiansted and on the
western boundary of the town dip mostly to west
of south, while those immediately to the east of the
town dip to south and farther out dip to south-by-
east, we may consider that we have found further
evidence strengthening the conclusion derived
from the arrangement of the rocks on the .south
side of the hills. It .seems then to be probable that
a cross axis of elevation in the ancient rocks fol-
lowed about the .same line as is now taken by the
remarkable cleft through the Christiansted Hills,
a cleft which perhaps indicates a like cross eleva-
tion on a smaller scale in more recent geological
times.

If we now pass northwards over the Christian-
sted rocks, with their southerly dips, we find the
same dips prevailing till we arrive at the Point at
the entrance to the harbour, on which stands the
lighthouse and the ruins of Port Augusta. Here
the strata are well marked, and although some-
what contorted, they dip to about southeast. Not
far east of the point the dip changes again, this
time to northeast, and it is evident that we have
arrived at a second anticlinal axis, the crest of a
second fold in the strata. Following up this north-
easterly dip we find that it extends along the north
shore to a point opposite the islet called Green
Cay. and is found in a few strata towards the south
end of that islet, and that it stretches southeast in .
a band across St. Croix, similar dips being found
at Boetzberg, at Lowry Hill, at Mt. Fancy and
" Madame Carty " on the south coast.

Beyond this strip northeastwards we find an-
other, in which the dips are once more to southerly
and southwesterly points, which may be traced
from the north coast past Green Cay and East
Hill School house, and appears to be represented
on the south shore by the rocks at the west end of
"Turner's Hole."

This narrow strip is succeeded by another band
in which northeasterly dips once more prevail, and
are shown in the rocks of the north shore from
Coakley Bay to east of Solitude Point. In the last
named point the strata are well marked and appear
along the beach, the dip being about 60 degrees to
northeast by east. In one or two places the beds
are vertical and even reversed ; but on the whole
the dip is as stated.

Following this strip with northeasterly dips
comes another with dips to southwest, changing
over, as we proceed eastwards, to southeast ; the
southwest dips being found in all the points from
"Solitude" eastwards to the west end of Tague
Bay, the southeast dips in some rocks near the
east end of Tague Bay.

The lines laid down in the map indicate the
various anticlinal and synclinal axes as thus ascer-
tained, and it appears to be certain that the same
great force which has produced the anticlinal
axis and the synclinal axis of the northwest has
also pushed up the strata into numerous great
ridges in the eastern part of our island.

Now York Botanical Garden I Ihniiy

QE226.V6 Q84 gen

Quin, John T./The building of an island

3 5185 00043 0890