UNIVERSITY OF CALIFORNIA.

FROM THE LIBRARY OF

DR. JOSEPH LECONTE.

GIFT OF MRS. LECONTE.

No.

VALLEYS.

PRINTED BY BALLANTVNE AND COMPANY
EDINBURGH AND LONDON

VALLEYS

AND THEIK RELATION TO

FISSURES, FRACTURES, AND FAULTS.

BY

G. H. KINAHAN, M.E.I.A., F.B.G.S.I., &c. II

OF H.M. GEOLOGICAL, SURVEY.

LONDON:

TRUBNER & CO., 57 & 59 LUDGATE HILL.

1875.
[All rights reserved.]

TO

HIS GRACE THE DUKE OF ARGYLL,

K.T., P.O., D.C.L., F.E.S., &c. &c. &c.

MY LORD DUKE,

Your Grace's contributions to

Physical Geology, and your able Presidential Addresses to
the Geological Society, London, have clearly manifested
that, whilst giving full weight to those arguments on Sub-
serial Denudation which have of late years been so domi-
nating with the modern school of Geologists, you have
not permitted them to exercise an undue influence over
your conclusions, but have been enabled to trace to other
and yet earlier geological agencies, also, the physical fea-
tures of our Earth's surface.

It is therefore with no ordinary satisfaction that I avail
myself of your Grace's permission to dedicate to you this
brief attempt to maintain, by observations in the field,
those views so ably advocated by your Grace.

I have the honour to be,
My LORD DUKE,

Your Grace's most obliged,

and most obedient Servant,

G. HENKY KINAHAN.

H.M. GEOLOGICAL SURVEY,
WEXFORD.

101203

LIST OF ILLUSTEATIONS.

COOMS AND TERRACES, BENNABEOLA . . Frontispiece.

PAGE

SKETCH MAP OF THE VICTORIA FALLS . . . .5

PLATE No. I ....... 9

PLATE No. II 58

PLATE No. Ill . . . . . . 110

GRAVEL TERRACE, DERRINKEE, ERRIFF VALLEY . . . 185

PLATE No. IV . 190

CONTENTS.

PAGE

PEEFACE . . . . . . . xv

INTRODUCTION ....... 1

Present features of the earth's surface, 1 ; Hutton's
theory, 1 ; Denudants and shrinkage fissures, 2 ; Meteoric
abrasion, 3 ; Hollows in esker gravel, 3 ; Hollows in marl, 4 ;
Joints, 4 ; Courses of streams, 4 ; Victoria Falls, 5 ; Valleys
of Suir, Barrow, and Nore, 5 ; Faults forming peaks, 6 ;
Faults not seen at surface, 6 ; Drift obscuring faults, 7 ;
Valley connected with faults and breaks, 7.

CHAPTER I.
SHRINKAGE FISSURES— RECENT DEPOSITS .... 9

Cracks, joints, and[faults, 9 ; Fissure, Lough-na-Sooderry, 10;
Moving bog, Clara, King's County, 10 ; Slip of mountain-
side, Glancastle, County Mayo, 12 ; Master and minor
joints, 13 ; Reclaimed bog, 14 ; Slips in recent accumulations,
14; due to the sea, 14; due to streams and springs, 15 ;
Effects of placing weights on weak ground, 16.

CHAPTER II.

SHRINKAGE FISSURES — OLDER ROCKS . . . .17

Cracks and joints, 17 ; Moisture in rocks, 17 ; Building con-
tracts, 18 ; Master and minor joints, 18 ; Regular and ir-
regular joints, 19 ; Joints in a barrel of Roman cement, 19 ;

X CONTENTS.

PAGE

Joint-lines in abandoned quarrys, 20; Joints, barony of
Burren, County Clare, 21 ; Wide and close jointing, 23 ;
Formation of faults, 24; Faults made artificially, 25 ; Slides
or heaves, cross-courses or lodes, 26 ; Lode, Glandore, County
Cork, 27 ; Sterry Hunt's endogenous veins, 28 ; Faults at
Mentreniat, 29.

CHAPTER III.

FAULTS . .-.,.... 31

To what they are due, 31 ; Caudelaria lode, Chili, 31 ; Con-
traction in rock masses, 32 ; Unequal shrinkage in the rocks
of Cornwall and Devon, 32 ; Faults in the older rocks, 33 ;
in newer rocks, 33 ; Simple and compound faults, 33 ; Step
faults, 34; Clifden, 34; Open fissures forming caves, 36;
Landslips, 36; Slip, Axmouth, Dorsetshire, 36; Slips,
Ulster, 37; Slips, Mount Sirban, India, 38; Slip, Pulleen
Harbour, County Cork, 39.

CHAPTER IT.

THE DENUDANTS, OR CARVERS OP THE EARTH'S SURFACE — SEA

ACTION ....... 40

The denudants, 40 ; Their work, 40 ; Sea action on the west
coast of Ireland, 42 ; On Arran and the coast of Clare, 43 ;
Connection between sea and inland cliffs, 44 ; Formation
of sea-cliffs, 45; Steps in connection with sea-cliffs, 48 ;
Formation of the " block beach," 49 ; Cliffs of Inishmaan, 50 ;
Marl cliffs in S.E. Ireland, 51 ; Slips in railway cuttings, 52 ;
Gravel and sand cliffs, 52 ; Meteoric abrasion in the vicinity
of the sea, 53 ; Dip of strata and marine action, 55 ; Escarp-
ments, both marine and meteoric, 55 ; The sea in dykes of
fault rock, 57 ; The sea produces cold and hot currents of
air, 58.

CHAPTER V.

THE DENUDANTS or THE EARTH'S SURFACE — ICE ACTION . . 59

Work of glaciers and rivers, 59 ; Physically hard and soft
rocks, 60 ; Ice a mechanical worker, 60 ; Glacial- work less

CONTENTS. XI

PAGE

than supposed, 62 ; Ice-dressed rocks, Spiddal, County Gal-
way, 63 ; Work of glaciers large at first, 64 ; afterwards
small, 66; Moraine-drift, West Pacific slopes, 66; Ice-
dressed rocks, West Galway, 67 ; Later glacial-work small,

CHAPTER VI.

THE DENUDANTS OP THE EARTH'S SURFACE — METEORIC ABRASION

All the surface of the earth not being denuded, 69 ; Jungle
and forest protectors, 70 ; Bog a protector, 70 ; Stones grow-
ing on the surface, 73; Grass a protector, 74; Meteoric
abrasion in South America and Abyssinia, 74 ; Present condi-
tions of Ireland, 75 ; Cliffs at Sheppy, Kent, 76 ; Lake District,
England, 77; Sun-work, 77; Cold, 80; Wind, 80; Cliffs,
Burren, County Clare, 81 ; Devonshire, 81 ; Slates, Counties
Cork and Kerry, 82 ; Mushroom rocks, 83 ; Effects of wet
years, 85 ; Rain and rivers, 86 ; Chemical action, 87.

CHAPTER VII.

THE RELATIONS BETWEEN FAULTS, OPEN JOINTS, AND THE FORMA-
TION OP VALLEYS ......

Professor Le Conte's theory, 88 ; Protrusions of irruptive
rocks, 89 ; Valleys of Dublin and Wicklow, 90 ; of Slieve Gal-
lion, County Derry, 90 ; Valleys in glacial- drift, 91 ; Dana's
theory of subglacial rivers, 92 ; Valleys of the Nore, Barrow,
Suir, and Glenniore, 92 ; Changes in the level of S.E Ireland,
93 ; Valleys on anticlinal axes, 94 ; Width of an anticlinal
valley, 95 ;, Folded strata, 95 ; Cliffs N.W of Knocknadober,
County Kerry, 96 ; Gorges along faults, 97 ; Faults making
marked features, 97 ; Fissures in Counties Cork and Kerry, 98 ;
Systems of valleys, Ireland, 99 ; Systems of faults, 100 ;
Dingle Bay and Mallow fault, 101 ; Post-carboniferous
faults, 101 ; Slieve Aughta, its faults and valleys, 102 ;
North-and-south valleys, Ireland, 106.

Xll CONTENTS.

PAGE

CHAPTER VIII.
THE LAKE-BASINS OF IAKCONN AUGHT . . . .108

Bog-basins, 108 ; Drift-basins, 110 ; Bar, Cleggan Bay, 110 ;
Bars of gravel in valleys, 112 ; Forests promote rain, 113 ;
Bars and lagoons, 113 ; Bar in Kylemore valley, 114 ;
Glacial bars, 115 ; Meteoric bars, 116 ; Mountain torrents,
117 ; Bars, Lake of Geneva, 118 ; Bars formed by landslips,
119 ; Lakes formed by beavers, 119 ; Eock-basins, 120 ;
Lough Conga, 123 ; Waterless rock-basins, 124.

CHAPTER IX.

COERYS WITH OR WITHOUT LAKE-BASINS . . . .126

Close on corrys in Kerry, 126; Corrys in Galway and
Mayo, 128 ; Cooses on the coast of Galway, 128 ; Marine,
ice, and meteoric actions, 132 ; Former climate in larcon-
naught, 133 ; Effects of sun's rays, 134; Altitude of corrys,
135 ; Churn holes and hollows in cooses, 136 ; Bars in corrys,
138.

CHAPTER X.
THE VALLEYS or SOME OP THE IRISH LAKES . . .140

Lough Neagh, 140 ; Lough Comb, 140 ; Sluggys, swallow-
holes, turloughs, pot-holes, and pipes, 141 ; Coole Lough river
system, 148 j Lakes and turloughs rising with the tide, 151 ;
Lough Mask, 151 ; Lough Derg, 153 ; Lake of Como, 157 ;
Subterranean passages, 158 ; River Fergus basin, 160 ; Sub-
terranean passages, Lough Corrib, 161.

.

CHAPTER XI.
GORGES AND RAVINES . . . . . .162

Abyssinia, 162; Lough Ashangi, 163; larconnaught, 164;
Lough Cooter and lakes in Clare, 166 ; Mount Sirban, 168 ;
California, 169 ; Namaqualand, 170 ; Galway and Mayo, 171.

CONTENTS. Xlll

CHAPTER XII.

THE RIVER VALLEYS OF SOUTH- WEST IRELAND : THE VALLEY OE

THE WEALD, AND THE FIORD OF KILLARY HARBOUR . 172

Jukes on valleys, South. Ireland, 172 ; Faults, &c., Cork and
Kerry, 173 ; Level of Ireland lowered, 176 ; Cork Harbour,
179; Esker sea, 182; Killary Harbour, 184; Derrinkee
gravel terraces, 185 ; Old sea-beaches and estuarine terraces,
186 ; Work done, Killary Harbour and Erriff valley, 188 ;
Estuarine deposits, 189 ; Shells, &c., in estuarine deposits,
191 ; Floatation of shells, 192 ; River beds and flats, 192.

CHAPTER XIII.

THE RIVER VALLEYS OF SOUTH-WEST IRELAND : THE VALLEY OF
THE WEALD, AND THE FIORD OF KILLARY HARBOUR — con-
tinued ....... 195

Valley of the Weald, 195 ; Subserial denudation, 196 ;
Objections to subserial denudation, 198 ; Former conditions
of the Weald, 200 ; Faults and breaks in the transverse
valleys, 203 ; Sea action in landlocked bays, 204 ; Gravel of
the Weald, 205 ; Romney Marsh and Pevensey Level, 206.

CHAPTER XIV.

THE LOCH LOMOND AND OTHER SCOTCH VALLEYS . . . 209

System of breaks, Scotland, 209; Loch Lomond a fiord, 210 ;
Deeps in Loch Lomond, 211 ; Features of the adjoining
country, 212 ; Formation of the basin, 213 ; Subterranean
outlet, 215 ; Postglacial breaks, 216 ; Leonard on some of
the Scotch valleys, 217 ; Glencroe and Glencoe, 217 ; Loch
Awe, 218 ; Savoie, Valais, and Bernese Oberland, 218 ; Loch
Fyne, 219.

XIV CONTENTS.

PAGE

APPENDIX.
FORMATION AND GROWTH OF SOIL OR SURFACE-MATTER . . 223

Rock weathering and disintegration, 223 ; Some rocks \
weather more than others, 224 ; Mud-land of Wexford, 225 ;
Chemical actions, 226 ; Darwin's theory of worm-work, 227 ;
Irish moors, 229 ; Vegetable growth combined with worm-
work, 230 ; Subsoils, 232 ; Growth of soil at Caerleon, 234 ;
Soil due to water and wind, 236 ; Kutch, 237 ; Ants, 237 ;
Other soil-producing animals, 239 ; Guano, 240.

PEEFACE.

THIS book was commenced some years ago, and
was to have 'been a joint production of my
colleague Mr J. L. Warren and myself. His
lamented and early death, due principally to his
over-zeal in the discharge of his public duties,
prevented the original plan from being carried
out ; it therefore devolved on me to complete
it alone, and since then much matter has been
collected, with which I have incorporated papers
that have appeared in different scientific maga-
zines and publications, on branches of the subject,
but at the same time the original style has been
adhered to, as if the joint- authorship still con-
tinued. This has been found necessary, as other-
wise the credit for the matter and facts collected
by Mr Warren, would be appropriated by me.

XVI PREFACE.

Some few suggestions that may appear in this
book might, perhaps, not be sanctioned by that
observer ; these, however, can be but few, as
most of the conclusions were discussed by us
together, and the constant result of our dis-
cussions was agreement. Any facts which are
stated without mention of any authority were
observed by one or other or both of us ; while
facts, the knowledge of which is due to other
observers, are given under their authority.

This book is, in the first place, a record of
observed facts, but the conclusions we have
arrived at may be controverted by others ; how-
ever, we have tried to avoid putting forward
anything that is not in accordance with prece-
dent and ascertained operations of Nature.

Plates Nos. I. and II. were drawn by the late
Mr Warren, while I am indebted to my colleague
Mr M 'Henry for Nos. III. and IV., and to Mr
Nolan for the characteristic sketch of the gravel
terraces in the Erriff river valley.

G. HENRY KINAHAN.

DUBLIN, March 1874.

INTRODUCTION.

PHYSICAL geologists are at variance as to the forces
which have formed the present features of the earth's
surface. It seems to have been formerly a very
general belief that the shapes of the ground are more
or less due to movements in the crust of the earth
which have opened cracks and fissures, elevating some
portions and depressing others, and that to these
movements, combined with marine denudation, the
features of the surface of the earth are due. Hutton
seems to have been the first to broach the theory
that the surface has been principally sculptured by
meteoric abrasion ; and now most of the working
geologists in Great Britain seem inclined to dis-
regard unduly every other kind of action. During
many years of geological research, we have noted
certain relations between the different kinds of
" shrinkage fissures," breaks, lake-basins, valleys,
and other features of the earth; and although formerly
we accepted in a great measure the theories of the
" subaerialists," we are now led to believe that the
different denudants must act in combination; — each
separately being incapable of doing much work,

2 INTRODUCTION.

while not one of the denudants could act efficiently
without the aid of external or internal heat to dry
and contract the rocks; because to the drying and
contraction of the surface rocks is due the minor
cracks and joints; and only in conjunction with these
shrinkage-fissures can any denudant work with effect.
Moreover, we are forced to believe that the faults and
breaks, due to the shrinkage of the earth's crust, have
materially assisted in giving the earth its present sur-
face conformation. Few geologists in these countries
now give any credit to faults, joints, and the like, as
having assisted in forming valleys or lake-basins,
while none give them the prominence to which they
appear entitled; but on the contrary, it has been
stated, " there is no necessary connection between
fractures and the formation of valleys." It has also
been stated, that in many cases the materials "washed
out of the different valleys could not have been origin-
ally softer than the materials of the intervening ridges,
as the corresponding strata on the opposite sides of the
valleys are of equal hardness." The latter statement,
however, quite ignores the fact, that if portions of the
ground are broken up and loosened in lines, by systems
of faults or joints, the intervening parts may be still
firm and unbroken; and when the shattered parts
are denuded away, the others would remain standing
in unbroken ridges and masses.

If meteoric abrasion is the universal denudant

INTRODUCTION. 3

some would wish us to believe, how is it that it has
accomplished in these countries so little work since
the glacial period, while the effect of marine de-
nudation in the rearranged drift is so apparent?
Many rocks, exposed ever since the glacial period to
meteoric action, have not as yet lost their glacial
dressing or striae ; while very little of the drift in the
valleys above marine influences has been removed,
and in other places no traces of this continuous de-
nudation can be detected.

In the Esker gravels of the central plain of Ireland,
but especially in the King's County, there are deep
bowl-shaped hollows. The vegetable soil or decomposed
drift on these gravels is always shallow, often only a
few inches in depth. This, in ordinary cases, might be
accounted for by its being washed away nearly as
fast as it was formed, by rain and runlets, the slopes
of these hills being always more or less steep. If such
was the case in the bowl-shaped hollows, there ought
to be at the bottom much more soil than on the slopes,
the continual waste of the land carrying down the soil
to the lowest level ; yet such does not appear to be the
case, the depth of the soil on the slopes and on the
bottom of the bowls being nearly equal, except when
the hollows are tilled. In these hollows, on account
of the nature of the drift, water rarely, if ever, lodges.
In the County Wexford much of the low country is
covered by a drift composed of either marl or clay, in

4 INTRODUCTION.

which cup-shaped hollows are not uncommon. The
King's County bowls seem altogether due to eddies,
or the piling up of the drift by transverse currents ;
while the Wexford cups seem to have been caused by
a subsidence in the underlying strata. At first,
probably, there were subterranean passages out of the
latter; but now these are almost entirely, if not totally,
closed, and there is now always more or less water in
them, in which aquatic plants grow, which eventually
produce a peaty accumulation. These accumulations,
if a constant denudation were going on from the sur-
rounding slopes, ought to be more or less earthy, or
ought to have layers and thin seams of marl or clay
in them, marking each summer's growth of the peat.
This, however, is not the case, even when the adjoin-
ing land is in tillage ; but on the contrary, as where
sections can be examined, it is found that the peat
tends to creep up over the drift.

Two or more systems of joints cross one another
more usually at acute than at right angles ; and we
find, on looking at the map of the world, that the
land is more inclined to form triangles than any
other kind of figure. The tributaries of rivers or
streams on sloping ground generally join them at
acute angles, rarely at right angles. It may be
asked, If the courses of streams are mainly due to
joint-lines and such like, why then are there not
networks of valleys, as each joint-line ought to be

INTRODUCTION. 0

more or less developed into a surface feature in its
whole length, and not only in part thereof? This,
however, is easily answered, as water flowing down a
slope denudes the weakest place, which must neces-
sarily be a joint-line or some such crack, and
eventually forms a channel along it. To this channel
it is confined till it meets another channel, cut by a
superior stream, into which it naturally flows, and
loses all power of continuing its original course.
This, however, is not always the case, as a stream
coming down a joint-line belonging to one system

Bird's-eye Plan of the Victoria Falls and River, after a Sketch

in the Dublin Exhibition, 1872.
a Victoria Fall ; a b c d e, river ; //////, joint lines.

may meet a joint-line belonging to another which is
better developed and more easily denuded, in con-
sequence of which it will leave its original course and
take to another. This is well illustrated at the great
Victoria Falls, Africa, where the water flows over into

6 INTRODUCTION.

one break, and from that finds its way into a second,
a third, and a fourth, so that the river's course below
the falls assumes an extremely acute S-shaped form.
At home it is illustrated in the ravines occupied by
the lower portion of the Suir, the Barrow, and the
Nore, in south-east Ireland, where the different
streams have excavations along different systems of
breaks ; while in general the breaks along whose
continuations those rivers originally worked are
now occupied by tributary streams. A remarkable
instance of how a river may leave its original joint-
line is seen at the junction of the Suir and the
Barrow. The former is the larger stream, yet it has
left the course it might have been naturally expected
to follow, and now flows in the continuation of the
break along which the Barrow came, previous to
their junction. Numerous other illustrations could
be given ; these details, however, are more suited to
the body of this book than to its introduction ; it is
therefore unnecessary to enter further into the sub-
ject.

Although valleys seem not to be formed without
the assistance of breaks or faults, yet all fault-lines
do not form valleys ; on the contrary, they may form
peaks and ridges. Nearly all the peaked summits
among the mountains of West Galway belong to
hills formed of quartz schist, and these rocks are
traversed by large dykes of hard "fault-rock," a

INTRODUCTION. 7

breccia having a matrix of either quartzyte or vein-
quartz. As these rocks are harder, and have resisted
denudation better than the associated rocks, many
of the peaks are on a line of dyke, or at the crossing
of two ; while other dykes form the summit of ridges,
or stand out as reefs across the hills, or forming
shoulders to them.

In other places no traces of the faults can be seen
on the surface of the ground. This has been espe-
cially remarked during the working of the different
coalfields, and it led an eminent geologist to state
that he could not see how there should be any con-
nection between faults and surface features, when
so many large faults in the coal measures are not
discernible on the surface of the ground. The oblitera-
tion of such fault-lines may be due to two causes :
these lines may be simple " slides," while the associ-
ated rocks are so similarly constituted that the de-
nudant (sea or ice) carved them evenly away ; while
in other cases the surface features due to faults may
have been obliterated by the subsequent deposition of
an envelope of drift. That drift often obscures these
features is proved by mining and other such work-
ings, as one pit may reach the rock in a few yards,
while another in its vicinity will have to be sunk
perhaps forty or fifty ; and in a drift country it is
generally found that most of the fault-lines, except
some that are post-glacial, are obliterated. It might

8 INTRODUCTION.

be said that all the post-glacial faults should be
apparent; this, however, need not be the case, as
the sea subsequently has, in many places, modified
the surface of the glacial drift.

In the following pages we will attempt to demon-
strate that, in general, valleys are connected with
faults or breaks, and that a valley or hollow could
seldom have been carved out unless there were cracks,
minor joints, or other shrinkage fissures, in which one
or other of the different denudants could work. The
majority of our examples will be taken from facts
observed by ourselves, principally in Ireland, but we
will also refer to what other observers have noted in
various countries.

PLATE I.

CHAPTER I.

SHRINKAGE FISSURES — RECENT DEPOSITS.

ALL rocks, no matter of what composition, are, in a
greater or less degree, traversed by cracks, joints, and
faults, and to explain the origin of these is the task
that first presents itself. In order to do this, we
must either make similar breaks artificially, or watch
what is going on at the present day. A recent de-
posit or accumulation, such as a bank of silt in a
river, lake, or estuary, or an alluvial flat un watered
by the lowering of a river, or a drained bog or moor,
when exposed to atmospheric influences, will crack as
it dries and contracts, sometimes irregularly (fig. 1,
PI. I), but often more or less regularly (fig. 2, PI. I.)
However, on account of the frail nature of the mate-
rials, rain, frost, heat, and the wind may more or
less obliterate the fissures, but some will remain open
to act as water-carriers if they have a fall ; they will
thereby be deepened, while the increase in their width
will probably be small. Numerous examples of such

10 SHRINKAGE FISSURES — RECENT DEPOSITS.

proceedings occur, especially in mountainous bogs.
One worthy of record was observed north-west of
Koundstone, County Galway. Here is a flat bog
bounding a lake ; and some years ago, during a very
dry summer, a crack opened in the former ; this was
taken possession of by the water of the lake, which
deepened and slightly widened it, thus forming a
connection between the upper lake and Lough-na-
Sooderry, so that now the surface of the water in the
former is always four feet lower than it used to be.

Cracks also form in flat bogs, and at different times
they have indirectly caused large tracts of the Irish
bogs to move. One of these movements occurred about
fifty years ago, near Clara, King's County, under the
following circumstances : — The drought of a very
dry summer not only opened fissures in the bog, but
also, as it would appear, in a great measure cracked
it away from the subjacent marl and gravel. Such a
process can be seen on a small scale on any boggy
mountain after a -few weeks of very hot sun. The
water seems to have afterwards got under the peat,
and when the inhabitants of the country cut their
turf, they severed the marginal connection between the
peat and the underlying strata, and the whole bog
moved away. The phenomena was thus described by
an eye-witness : — " I remember the bog moving. It
is about forty years ago, the year before the king
[George IV.] came to the Curragh. It was a very

SHRINKAGE FISSURES — RECENT DEPOSITS. 11

dry year, and the year the king came over was very
wet. I was then a small boy, and lived near the place.
It happened in June, on a Friday during dinner-
hour. The cows saw it first, for they all began
running away from the bog, and we thought it was
the flies were at them ; but then the barrows and
slanes began to tumble about, and the bog to move
up and down like the waves of the lake. It moved
as far as the small cabin on the bog that day, but on
the following Monday it again moved across the road
up the side of the gravel ridge (Esker) ; it tore up the
marl with it, and carried it along. We considered
that it was such a dry year that the lough on the
east side of the bog got under it, down through the
cracks, and floated it away. People from all parts
came to set up tents in the demesne to see it move,
but it never stirred since." In this case it would
appear as if it was the turf-cutters who by their opera-
tions had finally given occasion to the bog to move.
But usually in the case of moving bogs, the connec-
tion between the peat and the gravel or marl is cut
away by the action of a river or stream flowing at
a lower level, the bed of the bog having a slight
incline towards it; but once the mass begins to move,
its own weight may force a portion of it on to a
much higher level, as in the case of the Esker, near
Clara.
Movements somewhat similar to that now men-

12 SHRINKAGE FISSURES — RECENT DEPOSITS.

tioned have taken place on mountain sides when
cracks have opened across the slopes, as in these
water will collect, till eventually large masses float,
and afterwards loosen and slide down into the
valleys. A slip of this kind took place on the
mountains of Glancastle, near Belmullet, County
"Mayo, in 1867, and a description of it was written by
the Rev. P. Mahon, P.P., of which the following is an
epitome : — About forty acres of country, varying from
ten to fifteen feet in depth, broke loose from the
mountain-side and slid down into the Atlantic,
converting what had been a luxuriant dale into a
desolate valley. The slip was due to " the great
drought of the preceding two months creating a
vacancy between the peat and its gravelly substratum.
This was filled by the heavy fall of rain on July 19th,
by which the peat-covering of an entire mountain-
side was raised from its bed, broken up into huge frag-
ments, and caused to slide down the inclined surface,
carrying destruction in its course, until it spent its
fury in the Atlantic. The slope of the ground was
about one foot in fifteen." In this case it was a peaty
soil that gave way ; but similar slips may also occur
in drift, and they will hereafter be referred to when
we are describing bars and lake-basins in mountain
valleys.

In alluvium (sand, gravel, and silt) cracks are not
so effective in this way as in peats, since the sides

SHRINKAGE FISSURES — RECENT DEPOSITS. 13

shed from the effects of heat and wind or contact with
water ; yet in some cases what was originally a crack
may eventually become a watercourse.

When a section is laid open in a bank by a river,
or lake, it is usually found to be stratified, according
as materials of different composition, colour, or
texture may have been deposited in layers or strata.
In such accumulations two distinct kinds of cracks
or joints are formed ; one set (minor joints) are local,
and only affect a stratum, or two or more associated
strata, while the other (master joints) cut through
all the layers. The minor joints are, in general,
locally systematic — that is, in some layers, only, they
will all be regular, and in others all irregular. The
master joints on the surface are usually more or less
regular, but beneath they may be either regular (c, d,
fig. 3, PI. I), or irregular (a, c, f, b, fig. 3, PI. I),
as they take advantage of the weakest lines in each
successive stratum they pass through ; or even at
times they may for a while run along the stratifica-
tion, and if there be an open crack at the surface,
it may not be continuous downwards, the lower part
of the fissure being either to one side or the other of
the upper (fig. 3, PI. I.)

If two master joints cross, they form a greater or
less vacancy at the intersection (fig. 4, PI. I.) ; but
if three or more cross at one point, the opening will
necessarily be larger, not only on account of the com-

14 SHRINKAGE FISSURES — RECENT DEPOSITS.

bination of the fissures, but also because tlie pf eject-
ing angles of the intervening masses are liable to
break off or crumble away (fig. 5, PI. I.) Minor
joints may act similarly, and they are largely instru-
mental in causing reclaimed bog, unless well weighted
with clay or gravel, to return to its original condi-
tion. The process is as follows : — After the bog is
laid down in grass, it cracks and opens during hot
weather. The fissures do not afterwards close, but
their sides shed, forming muddy spaces round patches
of grass. Yearly this opening goes on, until eventu-
ally the grass land turns into innumerable small
heathery hummocks with soft bog between, moss
and heather having killed out the grass. A similar
process may occur in alluvial flats, except that rushes,
instead of moss and heather, usually succeed the
grass.

In any recent accumulation, one or more layers
may be composed of sand, marl, or some such material
that will "run" when a section is exposed, either
naturally or artificially. Fine sand and the like
usually runs, on account of the water it contains,
moving off and carrying the sand with it. Slips of
drift, due to this cause, may be studied on the coast
of Counties Mayo and Galway, in places where there
are accumulations of boulder- clay drift containing
lenticular layers and subordinate beds of sand. Some
of the latter, when exposed by the sea action, " run ; "

SHRINKAGE FISSURES — RECENT DEPOSITS. 15

while subsequently cracks form in the superincum-
bent mass, till eventually, having lost all support, it
slides away seaward. On this coast such subsidences
are usually not of very great extent, but in a few
cases remarked they were considerable.

Streams may act somewhat similarly to the sea;
and examples of their undermining and lowering
ground may be studied on the south slopes of the
mountain group called Slieve Arra, County Tipperary.
On these slopes there is a large accumulation of
boulder drift, which in places contains subordinate
beds of running sand. In the boulder drift the rain
and rivers have opened deep ravines, and if these
reach down to the sand, it runs, thereby causing
large subsidences in the drift. Some of these sub-
sidences are in steps (see plan and section, fig. 18,
19, PI. IV.)? as if tne ^ft when sinking had given
way successively along lines of parallel jointing,
thereby preventing the sand farthest away from the
vent having free egress.

Remarkable instances of subsidence are those due
to a bed of sand being carried off by a spring, that
may come to the surface, at any distance away from
the source, of the sand. As the sand must be sub-
tracted particle by particle, the subsidence usually
is gradual, forming more or less bowl-shaped
hollows in the surface of the ground. This, however,
is not always the case, as the ground may give way

16 SHRINKAGE FISSURES — RECENT DEPOSITS.

along joints or breaks in the drift, and thus form
hollows with perpendicular sides; but in such cases
the shape of the sides is generally soon modified by
meteoric abrasion.

Something may also be learned from railway and
other embankments, as they often subside on account
of the ground under them being weak. If the
foundation is bog, the peat will bend down at first
towards the embankment, but afterwards it will
crack in lines rudely parallel, and eventually form
fissures more or less wide, according to the depth the
embankment sinks. Gravel, in general, when it
gives way, acts very similarly to bog, bending down
to the embankment, and eventually cracking and
forming fissures. So also do some clays, but others
act like mud, which squeezes out from under the
embankment, and rises in curves. Clay will stretch
to a considerable extent, and may remain unbroken ;
but mud seems to crack immediately — at first, per-
haps, often irregularly, but subsequently, when it has
lost most of its moisture, regular fissures may be
formed in it. Subsidences may bend the different
strata, but in many cases they occur along a joint,
and thereby break the continuity of the beds or
strata, thus changing a joint into a dislocation or
fault.

CHAPTER II.

SHRINKAGE FISSURES — OLDER ROCKS.

WE have endeavoured to point out what can be
learned from the study of the formation of cracks or
joints in recent deposits; and if from them the
student turns to the observation of rock masses, he
will find that nearly similar laws appear to have been
followed in the jointing of all rocks of derivate origin,
no matter to what geological period or age they
belong. One marked difference, however, ought to be
pointed out ; namely, that in the older rocks, gene-
rally the joints are more regular and systematic.
There are, however, exceptions to this general rule.

It seems probable that all rocks, when deep-seated,
are more or less charged with moisture. This they
lose after being subjected to a drying process, whether
by atmospheric influences or internal heat. Rocks,
when dried, contract in a greater or less degree, accord-
ing to the composition of the rock; the contraction
being rarely equal in the vertical and in the horizontal

18 SHRINKAGE FISSURES — OLDER ROCKS.

directions. Hence in well drawn out building con-
tracts, it is specified that all stones should be laid
on their " quarry bed," as otherwise the settlement
of the masonry will be uneven. Dry rocks or stones
that have been for some time quarried contract less
than freshly quarried rocks. It may therefore be
suggested that stones, before being used for building
purposes, ought to be allowed to lose their quarry
water ; for if fresh moist stones are put into a build-
ing along with well dried ones, no matter how neatly
or finely the joints are laid, these must eventually
open more or less in certain places. Open joints are
often attributed to bad building, when in reality the
fault may have been in the mixture of stones in dif-
ferent stages of contraction. This often occurs in
buildings ; new fresh quarried and cut stones being
used as quoins and such like, while the intervening
work may be built of old stones, which have been
drying for years in another building. Different kinds
of stones contract in different degrees. This sub-
ject, however, seems not to have attracted sufficient
attention, as we have been unable to find the records
of any experiments on the contraction of rocks.

Eocks in situ must form by their contraction
joint-lines ; and as in the recent deposits, so also in
the older rock masses, there are minor joints only
affecting one or a few associated beds, and master
joints that cut through many strata. Minor joints

SHRINKAGE FISSURES — OLDER ROCKS. 19

seem to form when rocks are at or near the surface, but
some are deep-seated, as joint-lines may form at an
old surface, while subsequently newer strata may
have been deposited. In the old rocks these joints are
usually much more regular than in the recent accu-
mulations; nevertheless, in some beds of limestone
a jointing quite as irregular as, or even more so than,
that figured (fig. 1, PI. I.) may occur; and such
jointing, combined with subsequent weathering, will
change an even surface of limestone into a coarse
shingle, or into a number of irregular hummocks ;
each being surrounded by a deep hollow, and the
whole collectively having a somewhat similar appear-
ance to a tussocky bog ; both being due to the same
causes, namely, irregular jointing and subsequent
weathering. Jointing of this kind is not uncommon
in places among the limestone crags of Clare and
Galway; the interstices between these hummocks
varying from a few inches to yards in depth. We may,
however, remark that although we have mentioned
these localities as places in which these joints may
be found, yet they are not characteristic of the lime-
stone, for generally the jointing is extremely regular.1
A barrel of Koman cement, if left in contact with the
atmosphere, will become indurated into stone. Such
an artificial rock was used as the corner-stone of a

1 "Mem. Geol. Survey, Ireland," ex. sheets 85, 95, 105, 106, 113,
114, 115, 122, 123, &c.

20 SHRINKAGE FISSURES — OLDER ROCKS.

house; and on the outside it weathered similarly
and had the aspect of an argillous limestone. On
being broken, there were internally nearly parallel,
more or less regular, horizontal joints, and two sets
of vertical joints, which enable the block to be easily
broken into irregular cubical pieces. In the cubical
pieces there was a horizontal lining, seemingly due
to the packing of the cement in the barrel.

Joint- lines gradually opening can be studied in an
abandoned limestone quarry, where sheets of rock
have been uncovered, and left subject, for greater or
less periods of time, to atmospheric influences. Here
it will be found that in the parts longest exposed,
fissures have been produced along the joint-lines;
while in the places more recently stripped, the joints
remain in their original condition. The fissures are
partly due to meteoric abrasion ; but that contraction
has also partly formed them, is evident in the places
where the joints have cut through layers or nodules of
chert, this very hard kind of rock being nearly un-
affected by weathering, yet contraction has separated
one portion from the other. The connection between
contraction and jointing is very perceptible in such
rocks as hard conglomerates. In them the surfaces
of division will be found to cut through the
enclosed pebbles, and each part of any pebble will
exactly fit its fellow on the opposite side of the joint,
showing conclusively that the jointing could not be

SHRINKAGE FISSURES — OLDER ROCKS. 21

due to weathering. Nevertheless, the peculiar character
of a large proportion of joint-faces seems to indicate
that something more than mere cracking consequent
on shrinkage has been concerned in the formation of
them. This is perhaps particularly well illustrated
in granite, and also indeed in the hard conglo-
merates. The way in which the joint-planes often
cut smoothly and evenly through the matrix and the
quartz pebbles in such conglomerates, is a perfect
mystery, and not to be explained by mere cracking
or mere fracture of any kind, as the fracture-surfaces
of these rocks is often totally different in character
from the ordinary joint-surfaces. Haughton suggests
that these surfaces are due to an obscure tendency
to cleavage having previously existed in the rocks.

Our colleague, the late F. J. Foot, M.A., paid
particular attention to the jointing of the lime-
stones in the barony of Burren, Co. Clare, and of it
writes : —

" The main joints, in this district, range between
N. 45° W. and N. 45° E., the most prominent being
those from N. 5° E. to N. 10° E. These may often be
seen running in perfectly straight lines for several
miles. Sometimes the piece of rock between two of
these is traversed by numerous small parallel joints,
extending for the same distance, and cutting up the
rock into vertical laminae. The action of the weather
on these will in time wear away this intervening

22 SHRINKAGE FISSURES — OLDER ROCKS.

piece, and cause a deep open fissure. Sometimes
the main joints assume curved instead of straight
courses.

" The cross joints range from E. 45° K to E. 45°
S., the most common being probably about E. 20° S.
They are not nearly so well marked as the main
joints, never being traceable for any considerable
distance, and seldom running even for this short
length in straight lines. In many places there are
no visible cross joints.

"It is possible that the gentle southerly dip (or,
more accurately, S. 5° or 10° W.) is the cause of the
north and south main joints (or, more accurately,
those bearing N. 5° to 15° E.) being the most pro-
minent. The dip of the surface is the direction in
which water will flow ; any joint or crack in the
rock, therefore, lying in this direction, will be more
exposed to the mechanical action of the rain, than
one which does not lie in it. In the first case, the
water has its maximum velocity; in the second, it
will either lie stagnant, or flowing slowly, will exert
less mechanical force.

"As we go westward in this district, it would
appear that the main joints have more of E. in their
bearing. In the island of Innisheer the main joints
are most beautifully marked, running across the
island, and bearing constantly E". 17° E. There are
also numerous main joints bearing W. of N., and

SHRINKAGE FISSURES — OLDER ROCKS. 23

cross ones N. of E., but they are never traceable for
any great distance.

" The general dip of the surface on Innisheer is
S. 15° to 17° W., and the most prominent open joints
bear N. 17° E."1 This authority ignores the denu-
dation by wind. This force, however, as hereafter
shown (pp. 79 et seq), must have materially assisted in
weathering these joint fissures.

Joints may be very variously developed as to fre-
quency, for at one time the members of a system will
be wide apart ; while at other times they may be so
close as to cut up the rock into slate-like slabs.
Cleavage in rock masses is easily determined, but
the distinction between minor jointing, when con-
fined to a single bed, and cleavage, is often obscure ;
in fact, in some cases one phenomenon seems to
graduate into the other.2

The contraction of rocks is apparent in mineral
veins that traverse alternations of soft and hard
strata. If there has been no displacement of the
rocks (slide or heave) in either wall or "cheek," the
parts of the same divided bed will be found opposite
each other on each side ; and if there has been no
shift, there can have been no friction or rubbing to

1 "Mem. Geol. Survey, Ireland," ex. sheets 114, 122, and 123, pp.
21, et seq.

2 W. King, D. Sc. Prof, of Geology, Queen Coll., Galway, has studied
the connection between these two phenomena. To his papers on the
subject the readers may be referred (Report Brit. Assoc. 1858, p. 83.
Scientific Opinion, 1870).

24 SHRINKAGE FISSURES — OLDER ROCKS.

wear away the softer beds ; yet the lode will swell in
the soft strata, and contract or " choke " in the hard,
suggesting that during the drying process the ar-
gillous beds have contracted laterally more than the
arenaceous (fig. 6, PJ. I.) It may be said that the
rocks may have moved up and down, and finally
stopped in their original position. This undoubtedly
seems to be the case in some instances, but in
most others it is highly improbable. In Salisbury
Crag, Edinburgh, the joints (faults) in the igneous
rocks are mere lines ; while in the associated
derivate rocks, they are marked by a greater or less
thickness of " fault-rock. " Similarly in a bank of
silt, we find that the argillous beds contract during
the drying process more than the arenaceous.

Fissures and faults in strata are not solely due to
the unequal contraction of the different beds, as
many of them have been formed during the several
movements in the earth's crust. These latter move-
ments are generally supposed to be due to the interior
portion of the earth cooling and contracting more
rapidly than the outermost shell. The latter being,
in consequence, subjected to powerful horizontal
pressure, which continuing to increase with the pro-
gressive interior contraction, the exterior portion must
eventually yield in places.1 Other faults may be

i " Formation of the Features of the Earth's Surface." By Prof. J. le
Conte. American Journal of Science and Art. Third Series- Vol. iv.,
pp. 345, et scq.

SHRINKAGE FISSURES — OLDER ROCKS. 25

caused by a part of a bed or beds, swelling or expand-
ing, and thereby raising and breaking the superin-
cumbent strata. This latter phenomenon can be
studied on a small scale, in the following simple
experiment : — Mix some lime into mortar, and after it
is made, introduce pieces and fragments of unslacked
lime, then spread out the mass, and level it with
either a roller or trowel. As the introduced pieces
slack, they expand and raise the mortar over them,
sometimes forming regular systems of faults (a main
fault with transverse branches) ; at other times a dome
will first form, but this, if the expansion is great
enough, will eventually split, and caught-up portions
of the mortar are often elevated, just as we find
masses of an older igneous rock raised on a newer.
The boundary of these raised portions may be most
irregular, yet on examination it seems invariably
to be a combination of straight lines.

The widening of master joints, and the consequent
formation of fissures, seems sometimes to have gone
on gradually, while in many other cases they would
appear to have opened at different periods with
intervals of rest between each. This seems suggested
by finding in many mineral lodes layers in duplicates,
each set differing in texture, aspect, and composition,
as if each opening had been formed and filled prior
to the subsequent expansion. Jukes, however, points
out that the layers of different minerals in some lodes

26 SHRINKAGE FISSURES — OLDER ROCKS.

may not be due to their having been " successively
introduced, since all the substances may have been
in solution together, and circumstances having been
favourable at one time to the deposition of one sub-
stance and to that of another at another time."1

But this could not be the case in all lodes ; for in
some, such as the lode at Maumwee, West Galway,
the original lode stuff was metamorphosed contem-
poraneously with the associated rocks, while subse-
quent to that action a newer lode formed alongside
the older one. Other cases of subsequent contract-
ing are metalliferous strings and veins traversing
and cutting through the other minerals in a lode, or
a " rib " of ore may run for some distance along one
wall and then cross over to the other wall, evidently
occupying a crack due to shrinkage.

Mining operations have taught us that there are
three distinct kinds of fissures or breaks. These are
called by the miners slides or heaves, cross-courses
and lodes. A slide or heave is a simple single
break in the strata along which the beds on one side
have slid down or been heaved up (fig. 7, PL I.)
A cross-course is a break, the walls or sides of which
are separated one from the other, while the inter-
vening space is filled with a dyke or mass ^fault-rock
(fig. 8, PI. I.), that is, a rock made up of fragments
and the detritus of the associated rocks, or of materials

1 "Student's Manual of Geology," a New Edition, A.D. 1862, p. 359.

SHRINKAGE FISSURES — OLDER ROCKS. 27

forced up from below or dropped into the fissure from
above ; while a lode is a shrinkage fissure, or a fault
now filled with minerals and their associates. The
fault-rock generally found in cross-courses would
appear to be due to the rubbing up and down of one
wall of the break against the other, as happens with
the sides of a crack formed in a wall during an earth-
quake ; and in general the strata on either side are
displaced from their original position. This, however,
is not always the case, as in some instances the beds
of rock on both sides would appear to have returned
to their first positions, cross-courses being known to
cross lodes, and yet neither to heave nor slide them.
Some of these cross-courses may possibly have been
open fissures that were filled from above, but others
could scarcely have been so.

Most lodes, originally, were fissures due to the
shrinkage of the rocks. These eventually were filled
by minerals deposited from solutions ; and, as just now
stated, it is probable that in many cases the fissures
enlarged gradually. At Glandore Mine, Co. Cork,
there are three distinct formations occurring together,
and forming one great " mineral channel; " namely,
manganese-ores, hematite and fault-rock ; the latter
being the oldest, as the hematite occurs in a lode
that crosses and sends veins into the fault-rock, while
veins of the manganese - ores are found cutting
through both.

28 SHRINKAGE FISSURES — OLDER ROCKS.

That class of granite vein for which Dr Sterry
Hunt has proposed the name of " endogenous veins,"
is evidently allied to mineral lodes, as the rocks
now filling them were deposited from solution. This
is evident, as most of them are lenticular, that is,
die out in every direction ; consequently they could
not have been filled by matter injected into them. A
character possessed by them, in common with mineral
lodes, is, that in many of them there are successive
layers or ribs along the walls, usually of very similar
minerals, but always differing in texture. That such
layers, filling shrinkage fissures, have been deposited
successively, can in some instances be proved by veins
and strings branching from the inner layers, not only
into the outer layer, but sometimes even into the
adjoining rocks ; as if the more recent shrinkage had
affected, not only the rock mass, but also those parts
of the vein-rock that had been previously formed. As
slides, heaves, cross-courses, and lodes are closely
allied, one may graduate into another. The dyke of
fault-rock in a cross-course, or indeed in any fault,
may widen or narrow. If the rocks, through which
the fault passes, are alternations of hard and soft
strata, there will probably be a dyke of fault-rock in
the latter, while in the former its course may only
be marked by a line or mere parting; a cross- course
graduating into a slide or heave. This is often
found to be the case when igneous rocks are inter-

SHRINKAGE FISSURES — OLDER ROCKS. 29

stratified with sedimentary rocks; and Kenwood,
when describing East Cornwall, states that in
Mentreniat, " the whole strata seem broken up by a
succession of disturbances of a nature between cross-
courses and slides." Somewhat similarly a slide
may graduate into a lode, for in alternations of " soft
and hard ground," such as shales and grits, the lode
will widen in the former, while it may " choke out "
entirely in the grits, and only form a simple single
break. Cross-courses and lodes also merge into one
another, the fissures having been in part filled with
fault-rock, and in part by a mineral vein, or by a
combination of both ; the interstices in the fault-rock
having been filled with minerals deposited from
solution. Kenwood mentions a remarkable example
at Mentreniat,2 and such are not uncommon in other
localities.

Most of the shrinkage fissures beneath the surface
of the earth seem to be filled with either fault-
rock, or crystalline mineral matter, but those formed
at the surface are affected more or less by the
atmospheric agencies. If surface fissures occur in
level ground, or in ground from which there is only
a slight fall, meteoric abrasion will more or less
obliterate them ; but if they are on a slope, or there
is a subterranean drainage from them, the meteoric

1 " Cornwall Geological Transactions," vol. viii., p. 714.

2 Ibid., p. 713.

30 SHRINKAGE FISSURES — OLDER ROCKS.

debris will probably be removed by rain and runnels
as fast as it is formed. Consequently the fissure will
not only be kept open, but also enlarged, the denu-
dation generally acting more in depth than width.
The consideration of denudation would, however, lead
us away from the present portion of our subject;
and prior to entering into that, we must describe
more fully the connection between master joints and
faults.

CHAPTER III.

FAULTS.

IT lias been pointed out that some faults are due to
the unequal shrinkage of .strata ; others to movements
in the earth's crust. The latter, however, are, for the
most part, indirectly connected with shrinkage, as it
is the contraction of the interior of the earth that
causes the movements in the crust. Some faults are
due to the subtraction of matter, others to its expan-
sion ; as matter may be subtracted either by running
water or volcanic action, and expansion may be due
to vulcanism or chemical action.

As the composition of the rocks forming the
earth's crust varies, not only in passing from one to
another, but also in different parts of the same
mass (as one part of a bed may be more argillous,
arenaceous, or calcareous than another), different beds,
and even different parts of the same bed, may con-
tract unevenly. The Caudelaria lode, in the district
of Chanareillo, Chili, " is seldom more than six
inches wide when it crosses the hornblendic dykes ;
but though uniting with no other veins, it enlarges

32 FAULTS.

at the upper side twelve or fifteen feet, immediately
on entering the adjoining limestone,"1 thereby giv-
ing proof that the contraction in the limestone at
Caudelaria was much greater than in the hornblende
rock. It should, however, be pointed out, that part of
the vacancy in the limestone might possibly have been
formed by a subterranean stream prior to the deposi-
tion of the metalliferous vein, and that consequently
the vacancy need not have been wholly due to contrac-
tion. If in rock-masses contraction takes place in a
vertical direction, there must be unequal subsidences,
unless all the rocks are severally homogeneous in the
horizontal direction, which is rarely the case. These
unequal subsidences must take place along the lines
of greater weakness, which will be the master joints ;
and such movements must break the continuity of
the strata, and change the joints into dislocations or
faults.

Henwood's observations remarkably confirm the
connection between faults and the uneven shrinkage of
rocks. He states, in reference to the recorded examples
of lodes in Cornwall and Devon intersected by the
same cross vein : " There is no instance in which
motion in one direction, and of the same extent, will
restore the continuity of every lode so intersected ;
and such uniform motion will, in fact, produce, in
their relations on opposite sides of the cross-vein,

1 Henwood, ibid., p. 83.

FAULTS. 33

greater discordance than those which at present
subsist."

In rocks belonging to the Kainozoic and Mesozoic
epochs, the contraction in general has been less than
in the rocks belonging to the Palaeozoic epoch, while
the latter rocks present a marked contrast to the
metamorphic rocks. Consequently in the Kainozoic
and Mesozoic rocks, faults and fissures may be few
and small ; in the Palaeozoic rocks, they may be
numerous and large ; while in highly metamorphosed
rocks, they are often nearly innumerable.

Faults may be simple or compound. A simple
fault is that in which the movement has taken place
along a single line, and the motion has been so
regular that little or none of the adjoining rocks
were worn or torn away. In a compound fault, there
are two or more lines connected with the movement,
and a greater or less thickness of " fault-rock " has
in most cases been formed. If a movement takes
place along a straight or nearly straight master joint
(fig. 7, PI. I), little or no abrasion can take place;
but if a similar movement were to happen in an un-
even joint (b, c, fig. 8, PI. L), the pressure and
motion would break off the jutting-out portions of
the beds, as represented by the parts included be-
tween the dotted lines #, c, and £, d (fig. 8, PI. I.)
This figure represents a regular joint of this class,

1 Henwood, ibid., p. 370.

C

34 FAULTS.

while in nature such joints are usually more uneven
and often most irregular.

Another kind of compound fault is due to numerous
master joints in proximity, running more or less
parallel to one another, and all being concerned
more or less in forming the faulted ground ; or the
joints 'may branch off from one another, and after-
wards join again into one, as represented in the ac-
companying section and plan (figs. 20, 21, PL IY.)
The displacements may be tolerably equal along each
joint-line, thus forming what has been called a step-
fault (fig. 21). The movements, however, are often
most irregular, especially among the metamorphic
rocks. Long strips of country are sometimes met
with, occupied by " fault-rock," or strata so jumbled
up and mixed together, that it is nearly impossible
to separate one kind from another ; or, as is not
uncommon, the hard varieties of rock have crushed
up those that were softer, and masses of the first
will be enveloped in the debris of the others.

Such a tract of faulted country was observed in
West Galway, extending from Dogs' Bay on the south,
northward past Clifden to Cleggan Bay. This
broken ground is sometimes more than a quarter
of a mile wide, while in places it is represented by
a dyke of fault-rock only a few yards in thickness.
This is altogether due to the disposition of the
lines along which the different movements have

FAULTS. 35

taken place — they in some places running rudely
parallel to one another, in others branching off; or
all the movements may be confined to one narrow
line. That movements or faults are prone to occur
over and over again in nearly similar lines seems
proved here; as in this tract between Cleggan and
Dogs' Bays there are proofs of two ; while probably
three or four movements have taken place. The
first, post-silurian, but prior to the rocks having been
metamorphosed, as the fault-rock, after it was formed,
was altered along with the associated rocks. The
second later, but still pre- carboniferous. Of this move-
ment there are here no positive proofs ; as there are
no carboniferous rocks in the immediate vicinity ; but
movements during this period are known to have
taken place in other parts of the district. The third,
post-carboniferous ; the exact time of this movement
is uncertain. T^Q fourth, post-glacial.

As in master-joints, so also on fault-lines, open
fissures may form, when deep-seated, to be filled with
minerals, but when at the surface, to remain open
until they are more or less modified by meteoric
abrasion. As in the recent accumulations, so also
among the older rocks, a vacancy of greater or less
magnitude will probably be produced by this agency
at the juncture of two or more fissures (figs. 4 and
5, PI. I.) The open space due to contraction may
not always be continuous in one line, especially in

36 FAULTS.

contorted strata ; but it may be shifted to one side or
the other, if the line of least resistance in part coin-
cides with one of the lines of stratification (fig. 3,
PI. I. a, e,f, b). Open fissures forming caves, due
to such a cause, are not uncommon in some locali-
ties. They were noted in the sea-cliffs of Kerry and
Cork, while Kenwood, in his description of the mines
of Chili, figures lodes that occur in fissures of this
class.1

Landslips in recent accumulations have been
described, and very similar slips may occur in the
older rocks when at the surface. Some of these are
due to subordinate beds " running;" others would
appear to be caused l>y the subsidence of a tract of
country along a line of master joint or into a subter-
ranean vacancy, the origin of which we are unac-
quainted with, and can only guess at. An example
due to the running of a bed is the well-known land-
slip in the neighbourhood of Axmouth, Dorsetshire.
Here it is quite apparent that the rain water descend-
ing through the joints in the chalk and green sand
softened the underlying lias clay, which " ran," and
this, combined with a slight dip of the strata seaward,
induced a large tract of country about a mile long to
slip. From an examination of the land margin of the
" slip," it is apparent that the first and all subse-
quent slips have taken place along joints more or

1 Ibid., p. 82.

FAULTS. 37

less parallel to the coast-line, which broke the
connection between the seaward portion and the
mainland ; consequently, as fast as the foundation
gave way, the slips followed.

In Antrim., Ireland, along the chalk escarpment,
very similar slips have sometimes occurred. Open
joints have, at first, gradually formed in the chalk,
through which moisture has percolated to the under
beds, softening and carrying them away, till eventually
large masses of rock slide out into the lower country.
In the whole of Ulster it is hard to determine
whether the great slips, the remains of which are
apparent, are solely due to meteoric action, or
whether they took place when the sea washed the
base of the escarpment. During the present time,
and for ages past, such slips do not appear to have
taken place ; but it is quite evident that if the great
slips took place when the sea occupied all the low
country, other minor slips must have taken place
subsequently, probably immediately after the eleva-
tion of the land.

Along these escarpments two principal systems of
joint-lines may be observed, one rudely parallel and
the other nearly perpendicular to the line of escarp-
merit ; and to these, in a great measure, is due the
different features the basset of the chalk presents. If
joint-lines are nearly parallel to a line of escarpment,
as they open the water lodges in them, and even-

38 FAULTS.

tually prizes out masses of rock. In our special case,
however, it also acts on the soft lower beds (sand and
marl), and either carries them away, as may be seen
in the springs flowing out of the sand beds, or makes
them so soft and slippery that the superincumbent
mass has no foundation, and its connection behind
being already cut off by the joints, it must slide out-
ward. If joint-lines are perpendicular to an escarp-
ment, the action is quite different, as all drainage
takes place along these lines, and excavates ravines
with abrupt hills between ; and if these joints are near
together, the results of weathering in chalk will be
the carving out of " pillars," " needles," and such
like. Such a weathering does not, however, prove that
the escarpment is due to meteoric abrasion, as marine
action may work very similarly on joint-lines per-
pendicular to it.

Of landslips in Mount Sirban, India, Wynne thus
writes : — " The Nummulitic formation, as usual among
the border hills of the Punjab, is chiefly composed of
massive gray and blackish limestone, here alternating
with thick zones of dark-coloured shale. Its thick-
ness is very great, its stratification violently contorted,
and it possesses the same features, commonly ob-
servable, of profound gorges and ravines excavated
in it, high cliffs formed, and, upon slopes, of great
masses having subsided so as to produce complications

FAULTS. 39

of slippage often exceeding in amount the throw of
genuine faults."

Some slips are evidently due to a sliding along
an oblique master joint. Such a slide has taken
place on the north side of Ban try Bay, County Cork,
immediately west of Pulleen Harbour, a tract of
country a mile long, and about a furlong wide,
having slipped out seaward. Artificial landslips are
caused by coal mining and the like; large areas of
land subsiding into the vacancies left by the sub-
traction of coal, iron ores, clay and other minerals ;
while natural subsidences have taken place during
earthquakes, such as that which took place at
Lisbon.

Landslips teach us how faults on a small scale can
be formed at the surface of the earth, and from them
we can reason on the formation of most of the deep-
seated faults ; all being due to movements along lines
of least resistance, which must be master or other
joint-lines.

CHAPTEE IV.

THE DENUDANTS, OR CARVERS OF THE EARTH' S
SURFACE — SEA ACTION.

THERE are various agents to whose operations, com-
bined with the effects of contraction or shrinkage
(joints, cracks, faults, and the like), must be attributed
the diversified conformations of the earth's surface.
These carvers of the earth are — the sea, ice, the sun,
cold, heat, wind, rain, rivers, and chemical action.
Cold in this classification includes ordinary frost;
while ice refers only to the work done by glaciers
and icebergs. Heat and the sun also form distinct
headings. These two agents are kept separate,
.because their modes of action are entirely different ;
for although the latter is a source of heat capable
of forming surface cracks and other fissures,
yet many of the deep-seated joints must be due to
the effects of the internal heat of the earth. None
of these workers appear capable of doing much work
when unaided. The sea cannot act effectively with-
out the sun, chemical action, and wind, to open the
cracks, joints, and the like, and to raise the storm and

41

waves. Ice can do little work unless the rocks have
been previously ^affected by joints or other divisions.
The sun acts in combination with all the other denu-
dants; and in a greater or less degree, so do cold, heat,
wind, rain, rivers, and chemical action. The opera-
tions of the seven last-named agents are so intimately
connected, that in general they are classed together
under the names of subcerial or atmospheric denudation
and meteoric abrasion; but the individual work of each
is peculiar, and a short description of them will be
given hereafter. Although the names subserial and
atmospheric denudation are very generally used,
yet neither seems unobjectionable ; as, strictly speak-
ing, all denudation is subcerial, and all is more or less
directly due to atmospheric influences. Difference of
temperature causes the wind, the oceanic currents,
and the glaciers, also the evaporation that eventually
forms the rain and rivers.

It should be borne in mind that ice and the sea as
agents have this relationship : they are, for the most
part, mechanical workers dislodging masses of rock,
which are by the former ground up against one
another, or against the sides and bottoms of the
valleys occupied by glaciers ; and by the latter broken,
by being rolled over one another. Meteoric abrasion,
on the other hand, ordinarily only disintegrates rock
surfaces, preparing matter to be carried away by the
sea, ice, wind, or rain and rivers.

42

Some authors delight in describing the sea as
throwing its breakers loaded with stones and shingle
against cliffs, and thus wearing down even the
hardest rocks. The idea of " nature's artillery "
battering down a cliff may be very poetical, but it
involves a misconception as to fact. The whole of the
west coast of Ireland is open to the full force of the
Atlantic waves, which often rise hundreds, of feet;
" blue water " having on one occasion carried away
the water tanks at the upper lighthouse on the Great
Skellig, which, according to the ordnance map, is 380
feet above mean tide level ; 1 while spray has been
driven clean over the island of Valencia, so as to wet
the windows in Knightstown ; the cliff at the west
of the island being from 500 to 700 feet high ; yet
in no place on the west Irish coast did we remark
this "battering ram" process going on. On the
contrary, in those places most exposed to the waves,
the seaweeds usually grow luxuriantly, clothing
these rocks with a mantle. Abrasion by the sea will
take place in cooses, guts, and the like, but this is
due principally to the " back-wash." Stones when
carried in by the waves fall on a cushion of water,
and the force of the fall is broken ; but as the waves
retreat, they roll in the back-wash, over and against

1 It is remarkable what a height " blue water " will rise on sea rocks,
and against cliffs. A wave of the height here quoted, and of sufficient
magnitude, if it came in on most parts of the coast of Ireland, would be
higher than three quarters of the island.

THE EARTH'S SURFACE — SEA ACTION. 43

one another and the rocks. Consequently it is only in
cooses, or such like confined places, they are capable
of acting as abraders.

If the sea be watched during action, its principal
work, even in the softest shales, will appear to be
due to wedges of either air or water forced into
cracks, crevices, and other vacancies, by which rock
masses are prized out, and high cliffs are thus
undermined and brought down. The sea waves seem
never to- work but in conjunction, with meteoric
abrasion, which is often more rapid than the marine
worker. Consequently many cliffs are not perpen-
dicular, meteoric abrasion wearing back the upper-
most portion more quickly than the sea can quarry
away the base. Under favourable circumstances the
sea may form perpendicular cliffs, such as those on the
coast of Clare, where the sea readily carries away the
thickly jointed shales and grits of the coal measures ;
while on account of the horizontally of the bedding,
the rocks can stand with a vertical face, as if they
were blocks of masonry in a wall. On the west
coast of the Arran Isles, G-alway Bay, the sea has
formed peculiar cliffs, and as these have been
examined in detail, they may be described.

From the N.E. shores of the Arran Islands the
land rises in a series of eight cliffs, or huge steps,
which form continuous terraces, while from the
summit of the island there is a gradual fall south-

44

westward, ending, however, at the sea-board in cliffs
which, at the present day, are being formed by the
Atlantic Ocean.

The previously mentioned steps, forming continuous
terraces, are several miles in length; two of them
extending from the south-east to the north-west of the
great island. These, the third and fourth, reckoning
from the highest terrace, can be traced from Benaite
at Gregory's Sound, along the flanks of the valleys,
until they join into the sea-cliff, about half a mile
from the north-west point of the island.

The sea-cliffs on the north-east side of the island
are low, and are often replaced by strands, or shingle-
beaches. On the south-west they have taken a
definite character, being usually perpendicular, and
often over fifty feet in height. However, at the
north-west point of the island, under the shelter of
the Brannock Islands, there is a heavy shingle-
beach. From the north-west point, south-eastward
to Gregory's Sound, the cliffs are either perpendicular
or terraced. From Mweeleenareeava, a little south
of the Brannock Islands, to Doocaher, except for a
short distance at the " Blind Sound," the cliffs are
perpendicular, although at the base of some of them,
as will be hereafter mentioned, there are sea-terraces
or steps below the high water mark of spring tides.
At Doocaher the cliffs are about 100 feet high, and
from that towards the north-west they gradually rise

THE EARTH'S SURFACE — SEA ACTION. 45

to 234 feet at Corker; from which they lower by
degrees to the " Blind Sound ; " but north-west of
this, at Dun Aengus, there is an ordnance height of
265 feet, and they attain their greatest altitude (300
feet) about a mile farther north-west, a little south-
east of Polladoo. From Doocaher towards the south-
east, to the point called Illaunanaur, there are sea-
terraced cliffs (excepting a few short breaks), which
are surmounted by a rampart formed of large blocks.
This latter is called by Professor King, Galway,
" The Block Beach."

The cliffs on the west of this island are peculiar,
as in places they are terraced by the waves of the
Atlantic. Moreover, some of them are surmounted
by the " block beach." This peculiar accumulation
of blocks does not occur at all on the north-east
shore, while to the north-west it was only found at
the point due east of the north point of the Brannock
Islands. On Inish-Eeragh, the westernmost of the
Brannock Islands, there is also a block beach which
is thus described by Captain Bedford : — " On all but
the eastern side there is a margin of massive blocks
of limestone, upheaved by the violence of the sea, and
which now form a sort of barrier against its farther

encroachment The highest part of

the island is the summit of the upheaved beach
at the north-west side, which is 36 feet above the
mean level of the sea."

46 THE DENUDANTS, OB CARVERS OF

The north part of the north-west coast of Inish-
more, as before mentioned, is a perpendicular cliff
which either rises sheer up from the sea level, or has
at its base a< few steps.

The vertical .cliff seems to be caused, in a great
measure, by vertical master joints, some of which cut
through all the visible beds, while others only reach
the shale beds, that are found in these limestones at
the base of some of the inland terraces or steps, and
also as subordinate beds in the limestones that form
the south-west sea-cliffs. In the former case the
cliffs are perpendicular down to the sea, while in
the latter there are steps or sea-terraces at the
base.

Beginning at the N.W. to examine these cliffs,
the observer will find that immediately E. of
Mweeleenareeava there are master joints ranging N.
70 W., which extend down to the shale beds which
inland lie under terrace No. 5 ; and as the shales at
this place meet the sea at about half neap tide, there
is a perpendicular cliff above this level, while below
it there are steps.

From this for nearly a mile towards the S.E.,
the master joints bear E. and W., or a few points on
either side of that line, and as they extend below
low water level of neap tides the cliffs are perpen-
dicular. S.E. of Polladoo there are four sets of
steps at the base of the cliff, and the note made on

THE EARTH'S SURFACE — SEA ACTION. 47

the ground is as follows : — " Cliff over 250 feet
high. Two shale beds ; the cliff rises perpendicular
from the highest. These shale beds are supposed to
be the continuation of these under terraces, Nos.
2 and 3." South of Portmurvy there are from four
to six of these sea-terraces, and the cliff is less than
50 feet high. South of Gurtnagapple the cliffs are
low but perpendicular ; hereabouts, nearly E. and W.
master joints occur about two yards apart; and as
the sea undermines the cliff, masses of rock, tons in
weight, which are disconnected by these joints, topple
over and fall, forming a breakwater at the base of the
cliff. This breakwater extends for about half a mile.

At Corker there is a perpendicular cliff formed by
E. and W. master joints. In the face of the cliff
there are two shale partings about 40 feet asunder,
the lower being about 60 feet above half neap tide.
They seem to be the representatives of the shales
under terraces Nos. 3 and 4.

The small promontory called Nalhea is bounded by
N. 15 E. master joints ; here the shale beds have
dipped below the sea level.

South-east of Nalhea there are four or five sea-
terraces at the base of the cliff, and at Whirpeas the
cliff is about 140 feet higher than the level of neap
tide, a shale bed occurring about 40 feet above that
level. To the east of this, at Pollnabriskenagh, the
limestones are traversed by E. and W. master joints,

48 THE DENUDANTS, OK CARVERS OF

and the sea yearly causes great destruction of the
rock. This cliff, which is about 100 feet high, is
undercut at the base. At Bensheefrontee, the point
a little N.W. of Doocaher, the " block beach " sets
in and extends to the S.E. point of the island, having
only five small breaks in it ; three at the cooses or
small bays in the vicinity of Doocaher, one at the
coose called Doughatna, and one about 40 yards wide
at the Glassen rock — in all of which places the base
of the cliff is undercut, while that part which is sur-
mounted by the " block beach " is stepped. However,
although it is undercut and forms a cave at Doughatna,
yet below the cave there are six very low steps. The
highest part of the cliff on which this beach occurs
is in the vicinity of Doocaher, and about 100 feet
above the sea level ; while the lowest part, a quarter
of a mile west of the Glassen rock, is about 35 feet.
The S.E. point of the island, where the beach ends,
may be 100 feet high.

These steps at the base of the cliffs are usually from
four to seven in number, seemingly having been cut,
one by low water of spring tides, another by low
water of neap tides, another by high water of neap
tides, another by high water of spring tides, with one
or two intermediate steps when the limestones are
thin bedded, and the systems of joints do not extend
through more than one or two beds. However, in
places they are modified by master joints, along which

THE EARTH'S SURFACE — SEA ACTION. 49

cooses are cut; or perhaps two or more steps will merge
into one, according to the number of beds through
which the joint penetrates. At one place, east
of Carrickurra, there is a step, above high water of
spring tides, on which the " block beach " rests; at
this place the cliff is about 50 feet high.

The stones forming the " block beach " are cast up
during the winter gales, and some of them are of a
considerable size. A little south of Doughatna the
following observation was made : — " Great quarrying
seems to be going on here during the gales. Blocks
30 x 15 x 4 feet tossed and tumbled about." And
again, half way between Doughatna and the Glassen
rock there is this note : — " A block 15x12x4 feet
seems to have been moved 20 yards, and left on a step
10 feet higher than its original site." East and west
of the Glassen rock there are two caves which run for a
considerable distance inland, and connected with both
are " puffing holes."1 The western puffing hole is 85
yards from the sea margin, and the eastern 33 yards.
On the north-east side of the latter there is a small
" block beach," the blocks in which have all the
appearance of being yearly tossed about by the waves,
while more are added to it, and we may suppose some
sucked into the abyss below.

1 A perpendicular hole connected with a horizontal cave into which
the sea has access. During high tides and heavy gales, the compressed
air in the caves drives up the water in great puffs of spray through the
perpendicular hole.

D

50

On the west coast of Inishmaan, or the middle
island of Arran, the sea-cliffs rise in steps, as they are
followed southward from Trawtagh, until at Aillinera
they reach their maximum height (nearly 200 feet) ;
southward of this they gradually fall to nearly the
sea level at Allyhaloo, the S.W. point of the island.
Immediately south of Aillinera, at a height of about
170 feet, there is a "block beach," which is con-
tinuous from this point round the west and south-
east sides of the island.

South of Aillinera the " block beach " is on higher
ground than that on which it now occurs on any of
the cliffs of Inishmore. The cause for this is not
apparent, unless it may be that hereabouts the tides
run against the cliffs with greater force than else-
where, and thereby the waves may be enabled to hurl
the blocks to a greater height.1

The sea would appear to act more vigorously on a
coast-line that is sinking than on any other ; but, in
such a case, it should be remembered that the cliffs
or rocks, prior to having been exposed to marine
action, had for years, perhaps ages, been subjected
to atmospheric influences that loosened and disin-
tegrated them, leaving them ready to be easily
quarried and carried away.

The rocks above low water mark, on a coast-line, are
daily exposed to atmospheric denudation, and its

1 " Mem. Geol. Survey, Ireland," ex. sheets 104 and 113.

THE EARTH'S SURFACE— SEA ACTION. 51

influence on soft strata is very apparent; while in
places it seems to be the principal denudant, the sea
acting chiefly as a carrier.

Margining the sea in south-east Ireland, there
extend, for miles, cliffs of marl which are being
constantly worn away, yet the sea seems to have
very little effect on them. Heat opens joints in the
marl, thereby leaving it a prey to meteoric abrasion ;
while the principal work the sea does is to act as a
carrier, and remove the debris brought down within
its reach. As in the case of the formation of chalk
escarpments previously mentioned, so here also, there
are forming two systems of joints that regulate
the denudation, one being nearly perpendicular, and
the other nearly parallel to the coast-line. In the
first, meteoric abrasion widens the joints and denudes
the marl into transverse ridges or pinnacles, the joints
being near together ; but if the joint lines are nearly
parallel to the coast-line, they become frequently
filled by the rain, and masses of the marl are forced
to slide outwards. Thus the denudation of the cliff
takes place from the top downward, and not from
the bottom upwards, as ought to be the case if the
sea was the principal worker. Extreme marinists
would claim these cliffs as seawork, and if eventually
the land is elevated and they form an inland escarp-
ment, extreme subcerialists would point to them as
due to meteoric abrasion ; while neither force unaided

52

could have made them. Sea work alone would make
but little impression on the marl, and the atmos-
pheric agents, unless a river flowed all along at the
base of the cliff, would change them into a slope ; but
when both work hand in hand, meteoric abrasion
prepares the marl to be easily carried away by the
sea. If such cliffs are only examined during wet
weather the connection between the cracks and the
denudation is very obscure, as the rain and moisture
obliterates the cracks. Such places should first be
examined during fine dry weather, when the different
systems of cracks can be plainly seen and studied ;
and if subsequently the same place is explored in
rain the mode of work of the atmospheric agents is
apparent.

Very similar slips to those just described, the
result of a similar cause, take place in railway and
other artificial cuttings through marl, clay, and the
like. These, from what we learn in the cliffs, might,
in a great measure, be prevented by making artificial
joint lines (cuts) in them, perpendicular to the line
cf railway, which would act as drains to let off all
the water from the transverse joints, and thus
remove the cause of danger.

In some climates, hardened gravel and sand, sandy
clay, or any other clayey drift, may form perpendicular
cliffs to a sea margin ; the sea action working away
the lower portion as fast as meteoric abrasion denudes

THE EARTH'S SURFACE — SEA ACTION. 53

back the upper. In such accumulations the assistance
rendered by cracks and other shrinkage fissures seems
to be at a minimum, as marine action at the base of a
drift cliff washes out the clayey matrix and carries
away the rest, while the upper portion is disintegrated,
causing the contained pebbles and blocks to drop out.
If the cliff is exposed to the sun or a dry wind, the
surface of the drift will necessarily crack; but regular
systems of joints are rarely formed. In some places,
however, generally with wide intervals between each,
there are joints or faults. These, if perpendicular, or
nearly so, to the line of cliff, are being worked along by
the sea and the atmospheric agencies, and form cooses
or small bays. Soft sandstones, conglomerates, or the
like, may be worked similarly to hardened gravel and
be cut into perpendicular cliffs.

In the vicinity of the sea, meteoric abrasion would
seem to be more active than inland. On the coast
of Cork the slate beds at the coast are much more
weathered than elsewhere, since the sheet of ice that
once covered that county has melted away. Inland
the slates are ice-dressed, but in sea-cliffs the rock is
fast being denuded along the joints and cleavage lines,
so that the surfaces of the rocks may be compared to a
number of knife edges ranged alongside one another.
On the Arran Islands the limestone has weathered
away from four to six inches since the glacial period,
as proved by the unweathered pedestals of limestone

54 THE DENUDANTS, OR CARVERS OF

under the erratic blocks, while inland similar pedes-
tals are seldom three inches in height. In Galway
it is known, by the veins of segregation (granityte)
in the granite, that rocks of this class have weathered
in the proportion of two to 'one, as they are respectively
at, or away from, the sea.

The sea also appears to affect the colour of some
rocks. In Kerry, inland, the purple rocks weather red,
and those of a green colour, yellow. At the coast the
first become a whitish blue, while the green only
seem to be given a brighter tinge; and on the north
of Galway Bay the Felstones near the coast were
remarked to weather into a colour different from that
of the same rock when inland. Marine action is
often represented as forming a plain of denudation ;
but marine plains are not necessarily formed by
denudation, as they seem to be as often due to filling
up as to denudation. This is evident when tracing
any old sea margin, such as the 350 feet sea-beach in
Ireland, which is more often marked by the terraces
due to filling up than by the steps cut in the hill-
sides. To form a true plain of denudation the land
ought to be perfectly stationary ; and then, the active
part of the sea being at the level of the breakers, a
plain may be cut ; but even then there are so many
different causes to affect it, that rarely off a coast-line
will a true plain of denudation exist. If the sea is
working on homogeneous or nearly homogene6us rocks,

THE EARTH'S SURFACE — SEA ACTION. 55

especially if the bedding is nearly horizontal, it can
cut a plain ; but if the rocks are of different hard-
nesses, and are dipping at high angles, no such work
can be accomplished. In the first case the coast-line
ought to be in long gradual curves, but in the other
it must be quite irregular ; numerous headlands and
bays alternating ; the headlands indented by cooses
and guts ; while islands, carricks, carrigeens, and
skelligs lie off the coast and dot the bays, and the
soundings are quite irregular — in some places being
deep, in others shallow.

The deeps and shallows off a coast-line seem, in
a great measure, to depend on the dip of the rocks,
and appear to follow recognisable laws : rocks
dipping seaward at a low angle form low shore-lines
and shallow soundings; rocks dipping inland form
perpendicular or overhanging cliffs and deep sound-
ings ; while highly inclined or perpendicular strata
striking out to sea form most irregular coast-
lines, consisting of bays and headlands, with
numerous islands, rocks, and shallows lying off the
coast, according to the hard or soft nature of the
different beds of rock. These rules maybe altogether
modified by either jointing or cleavage; as one or
both of these structures may be more conspicuous
than the stratification, and direct the operations of
the denudant.

Escarpments in general follow the basset or out-

56

crop of beds, and the base of an escarpment is often
inclined in the direction of its length. From this the
subserialists argue that escarpments must be formed
by meteoric abrasion. This, however, does not
appear to be sound reasoning, as the same cause
which might induce meteoric abrasion to work along
a line of beds, would also similarly direct marine
denudation. On any coast-line, if the strata are
more or less flat, the sea works principally along one
bed, following it up and down ; and even if there are
anticlinal curves, it will follow the beds over them,
forming a point or headland ; and in such places the
sea seems to act more vigorously ; as the waves
dash up the slopes with fury, carrying blocks of
stone, and the latter in the back-wash abrade the
rocks, thus aiding the mechanical force of the sea.
Or the sea action will similarly follow up a bed that
is striking away from the coast-line, and rising out
above the normal level of the waves ; in this way
escarpments will be cut by the sea at higher levels
than the true coast-line. Farther inland, the meteoric
abrasion may also be acting along these beds, and
forming an escarpment, so that, if the land rose, there
would be one continuous scarp, in part due to the
sea, in part to atmospheric influences. This is well
exemplified in the previously described cliffs of Arran,
Galway Bay ; as there the sea is forming cliffs based
on certain shale beds, while, in the interior of the

THE EARTH'S SURFACE — SEA ACTION. 57

island, meteoric abrasion is acting very similarly on
the same beds. It may also be seen in numerous
places on the coast of England. The sea, nearly
everywhere, tries to follow the softer beds under the
chalk, and would do so but that the inhabitants have
for ages placed barriers to protect these soft parts of
the coast from the ravages of the sea, but the chalk
they can leave unprotected; while inland, meteoric
abrasion has modified the chalk cliffs into slopes,
and is said to be also wearing away the underlying
softer beds. In Ulster, Ireland, there are also chalk
escarpments, due both to marine and atmospheric
denudation. This subject will, however, have to be
again referred to when we are comparing submerged
and elevated sea-formed valleys.

The rock, or rather the debris of the rocks (Fault-
rock), included between the walls of a fissure, is in
many cases softer and more easily denuded than the
associated rocks. The waves will work with vastly
greater effect in such fissures than on the adjoining
rocks, and thereby excavate long narrow guts that
may be of great length, although only a few yards
wide. Many straits have evidently been so formed, the
sea working along, and excavating out a dyke of
fault-rock across a promontory, thereby eventually
forming an open fissure, and dividing one portion
of the land from another. Some of these guts are
open to the sky, but others may occur as long,

58

narrow caves ; the latter instances proving that the
sea is capable of working along the fault-rock much
faster than meteoric abrasion.1 Some of the deep
narrow straits in South- West Cork are remarkable, as
the old walls of the fissures still exist in part, show-
ing the original hade or underlie of the fissures.
This is well exemplified in the Crowhead promontory,
barony of Bear ; the shore of the mainland and the
cliff on Crow Island, hading S.W. at an angle of 75°
(fig. 13, PL II.), as if the two had been separated by
a clean cut.

In conclusion, there is one effect of the sea which
may be mentioned, though but indirectly related to
the present subject — namely, its power of producing
hot and cold currents of air, as these materially affect
the land on which they blow.

1 In places on the west coast of Ireland, may be found two caves,
one above the other, the lowest being now in process of excavation, while
the higher one was cut when the land stood at a lower level. Would
not such double caves suggest the idea that the land must have
risen quickly between the formation of the two ? for if the rise was
gradual, the intervening rock should have been excavated away.

PLATE II.

Fit. 13

MAP OF LOUGH CONGA.

CHAPTER Y.

THE DENUDANTS OF THE EARTH'S SURFACE ICE

ACTION.

GLACIAL denudation, seemingly, ought to be con-
sidered a different action to meteoric abrasion, as
these two forces work so differently. A glacier has
been said to belong to the atmospheric denudants, as
it is a river of ice, formed from snow ; but compare the
work a glacier and its tributaries can do with that of a
river and its tributaries. The tributaries of the first
are beds of snow and ice, while those of the latter
are all the chemico -fluvial forces combined. The
glacier and its tributaries work altogether by
mechanical action, being confined to planing and
triturating rock, and quarrying, by tearing off masses
of rock ; while the chemico-fluvial denudation is due
to chemical and mechanical action combined. The
latter is quite different to that exercised by ice, in
this respect, that it is principally carrying away
materials loosened by chemical action, the only
trituration it accomplishes being that done in river-

60 THE DENUDANTS OF

rapids and mountain torrents ; but it does not appear
capable of planing down a rock ; and ice, as icebergs,
may possibly be able to denude the sea-bottom, on
which none of the other forces can act, except, per-
haps, very strong sea currents. Many rocks, such as
doleryte, dioryte, diabase, granite, some limestones,
&c., are physically hard, while they are chemically
soft; others, such as slates, schists, clays, &c., are
physically soft, while they are very little susceptible
of chemical decomposition. The former, therefore, are
easily denuded by meteoric abrasion, and the latter
resist it. Also while a planing action, such as that
exercised by ice, would be resisted by physically hard
rocks, it could easily excavate and cut away the soft
ones ; and are not these the results found in nature ?
.In a country dressed, planed, and etched by ice,
all the physically hard rocks have formed features
from a few feet in height to hundreds or more ; but
since the ice has disappeared the meteoric agencies
have had their sway, and these rocks are now
weathering fast; while the chemically hard but
physically soft rocks — those that under the old
regime suffered most — are now almost perfectly
unmolested.

Ice action, similarly to marine action, as before in-
timated, is principally a mechanical worker, wedging
out and quarrying masses of rock. It, however, seems

THE EARTH'S SURFACE — ICE ACTION. 61

to have a greater power than the sea in one respect
— viz., that it is capable of lifting up blocks out of
their places and eventually carrying them away. In
West Galway, during winter, the water will freeze
under large blocks of stone and lift them, though tons
in weight ; now in a glacier the lifting power ought
to be much greater, when the ice is not only under
the blocks but all round them. Fractured rock, such
as that which fills a fissure, is more liable to be
denuded and carried away than unbroken rock ;
therefore, if ice moves over ground traversed by
fissures, especially if the direction of its movement
coincides with the bearing of these breaks, the ice, as
it moves along, must catch up and carry away all the
loose portions ; and if parts of a dyke of fault-rock
are softer or looser than the rest, the ice will scoop
out hollows in those places. If two or more fissures
cross one another at one "or different points, the rocks
in the vicinity of the points of contact will be broken,
and at such places ice should be able to work with
facility and excavate out hollows, the size of these,
both as to depth and width, being in accordance
with the amount of rock ruptured and the magnitude
of the moving glacier that acted on them. From
this it is apparent, that when fissures cross one
another there would be a large irregular basin opened
out, while if two fissures with broken rock between

62 THE DENUDANTS OF

r
J

ran nearly parallel, tlie excavation would be long and
narrow.

The work done by glaciers on their beds may appear
at first sight considerable, as the rivers always flow-
ing from them are ever turbid and white with the silt,
formed by the trituration of the blocks and fragments
of rock in the ice grinding against one another,
and the sides and bottoms of the valleys.1 Moreover,
this work is never ending from year's end to year's
end, as long as the glacier lasts. On consideration,
however, it is apparent that the solid matter contained
in glacial rivers, is probably far from giving a true
indication of the real work done by a glacier in
abrading the rocks it passes over ; as the silt held
suspended in the waters of the glacial river is not
solely due to the abrasion of the rocks passed over,
since much, if not most of it, may have been formed
from the blocks in the glacier abrading one another.
Some of these blocks may have been lifted by the
ice and carried away by the glacier, but many of
them may have fallen from the adjoining hills on to
the glacier, having been dislodged by meteoric
action, to find their way afterwards into the body
of the glacier through crevasses. Also innumerable
particles of rock are carried on to the surface of a

1 Hayes says, " The ice was perfectly pure and transparent " (of
"Tyndall glacier"), "and yet out of its very heart was pouring the
muddy stream of which I have made mention." — " The Open Polar
Sea," p. 436.

THE EARTH'S SURFACE — ICE ACTION. 63

glacier by wind, and all such auxiliaries to quantity
must be subtracted from the real amount of actual
work done by a glacier on its bed.

Ice work is somewhat similar to sea work, in that
both agents are principally mechanical workers ; yet
marine action appears incapable of performing as
much denudation on ice-dressed rocks as elsewhere.
This is very apparent west of Spiddal, Co. Galway,
and in other places on the coast of Ireland, where
ice-dressed rocks have resisted the action of the sea,
although exposed thereto for ages. This would
appear to be due to the ice having come after
meteoric abrasion, and removed all the rocks and
debris that the latter force had loosened, and left ready
to be quarried and carried away; also to its having
ground the remainder into smoothly-rounded forms,
over which the waves would sweep with little effect,
therq being few roughnesses or abrupt inequalities to
offer resistance, and to afford them a handle by which
to work. Subsequently, but prior to the sea being
capable of executing any great quantity of work, the
rocks would again be exposed to atmospheric influ-
ences to open up the cracks and joints. The action
of ice would, after a time, even render the rock less
susceptible to itself, for when the loosened portions
of the rock are gone, the pressure and friction of the
glacier would be calculated not only to smooth and
polish it, but also to harden what remained, as hap-

64 THE DENUDANTS OF

pens in polishing a stone. At first the polishing putty
removes all loose particles, but afterwards it not only
smooths but also hardens the surface, and we find
that polished marble bears the weather longer than
a plainly cut limestone, or a sawed sandstone better
than a chisel-dressed one.1 The latter case is well
exemplified in buildings, such as those of the colleges
in Oxford. There it may be observed that the saw-
ing of the sandstones has formed on the outside of
the blocks a thin sheet or coat, impervious to the
weather ; consequently the weathering does not take
place from the outside surface, but has to work side-
ways in under this shell of rearranged particles ; but
once they peel off, meteoric abrasion gradually wears
away the rest of the stone. The action of ice, how-
ever, would seem to be more like that of polishing,
as the hardening process appears to extend much
deeper into the rocks, and instead of forming only a
hardened shell or envelope, the effect seems gradu-
ally to die out in depth. If, therefore, a glacier is
formed in a valley, the rocks of which have been for
years exposed to meteoric abrasion, the work done

1 In burnished metal there is undoubtedly a rearrangement of
particles, and 'this seems to be so in highly-polished marble also, but it
has been questioned if such can be in ice-smoothed surfaces. We
have, however, carefully examined into the subject, and find that in
sandstones, such as the carboniferous sandstone of Mayo, a thin shell
of rearranged particles forms on the surface of the rock. In such rocks
as limestone there is a rearrangement and hardening gradually dying
out downwards, while in such rocks as granite we could detect none.

THE EARTH'S SURFACE — ICE ACTION. 65

at first must be large ; but after the disintegrated
and loosened rocks are removed, the effects of the
ice must gradually lessen, as its own polishing of
the rocks it passes over destroys its opportunity of
exercising its abrading powers. That this is the
case seems proved by two, and in places, even three
or four, distinct systems of striae being preserved on
one and the same rock-surface; these having been
cut evidently by ice-streams which flowed at differ-
ent times in different directions, and sometimes
even in nearly opposite courses. In West Galway
there are various systems of striae, some going west-
ward, others south-east or north-west, and on one
rock-surface two or three different movements of the
ice are recorded.1 • The newer stria3 must have been
engraved by an ice-stream of considerable magnitude,
which probably existed for a long time. If a glacier
is capable of much denudation, all previous rock
markings, especially such small ones as striae not
the tenth of an inch in depth, should be obliterated
by it. Nevertheless, this is not the case, but in
some localities the oldest striae are so distinct that
the relative ages of striae on one rock-surface might
be questionable, were it not that in other places
their true ages were proved. It may be asked, If

1 " General Glaciation of lar-Connaught and its Neighbourhood,
with a Map." By G. H. Kinahan and M. H. Close. Hodges & Foster,
Dublin.

E

66 THE DENUDANTS OF

a glacier, after working for years, cannot grind out
scratches not the tenth of an inch in depth, how has
it been able to form the roches moutonnees or ice-
dressed hummocks ? These, however, were princi-
pally formed when the ice first occupied the country
and the action of the glacier was at its maximum,
carrying away the weathered and softened portions of
the rocks. If we examine a weathered mass of rock,
we find that the atmosphere has affected it more or
less deeply, the lower margin of the weathered por-
tion being a line made up of a series of curves that are
abrupt, if there are sharp inequalities on the surface
of the rock, but are gentle if the surface is even or
nearly so. If an abrader such as ice were to attack
such surfaces, the weathered portion would be quickly
removed and leave a flowing outline similar to that
of an ice-dressed hnmmock. A second ice, passing
over such a surface, would have no weathered portions
to remove ; consequently it could not abrade the
surface like its predecessor, or obliterate all the
scratches and ruts produced during the passage of
the first sheet of ice.

A glacier when it first occupies a country is charged
with the detritus due to weathering, and if it dies
out previous to all this contained matter being
carried away, the country it occupied will be
covered by hummocks of rocky moraine drift, as
proved by King in his explorations of the dying out

67

glaciers on the West Pacific slopes.1 If, however,
a glacier traverses a country already cleared by ice
action, this ought not to be the case, for (similarly
to marine action acting on glaciated rocks), all the
loosened rocks would have been removed previously,
and the new force would have to act on a hardened,
planed, and more or less smooth surface ; consequently
there would be few or no inequalities for it to act on,
no debris for it to gather up, and few tools with
which it could abrade and triturate the rocks.

In West G-alway large tracts of ice-dressed country
were noted, in which there is scarcely any drift and
only a few erratic blocks. In some places marine
denudation may have removed the drift since the ice
melted away. This may be possible when the country
is below the level of the margin of the " Esker Sea "
(350 feet above the present sea level) ; yet it is not
probable, as the hummocks of rock not only give
evidence of having been planed and grooved, but also
in places still retain their etched and polished surface;
and although the groovings might survive the abrad-
ing of sea-tossed blocks, yet the polishing and etching
could scarcely escape. Furthermore, in other places
the ground is so high that marine action could not
have reached it during the " Esker period;" and it

1 " On the Discovery of Actual Glaciers on the Mountains of the
Pacific Slope." By Clarence King, U.S. geologist. The American
Journal of Science and Art. Third Series. Vol. i. pp. 157, et seq.

68 THE DENUDANTS, ETC.

is evident that previous to that time, the last occupier
of the hills was ice ; consequently we are forced to
believe that in such elevated situation the glaciers died
out, leaving little or no rock detritus after them.

At one time we put much more faith in the abrad-
ing powers of ice than we now do, but experience
teaches that first impressions are sometimes deceptive,
and that often the more a subject is studied the more
apparent becomes the necessity of modifying first
ideas. Undoubtedly, under favourable circumstances,
ice must be capable of executing a considerable
amount of work. This is also true of all the other
denudants, but none of them can operate with advan-
tage unless it has received aid from its fellow- workers.
If ice, as long as it continued moving, had the same
denuding powers, we could have no such thing as an
empty rock basin, as the ice when it finally melted
would be full of blocks and debris, and would more
or less fill up the hollow. If, however, ice has less
opportunities of denuding the longer it works, we
might in time have an ice pretty nearly pure, so
that when it finally melted there would only be a
mere trace of drift left by it; and this seems to
have been the case in many of the rock basins in
lar-Connaught, as the only deposit in them is a
peaty one of a quite recent age.

CHAPTER VI.

THE DENUDANTS, OR CARVERS OF THE EARTH'S
SURFACE METEORIC ABRASION.

IN the last two chapters it has been shown that
neither the sea nor ice have much power as denudants
unless aided by meteoric abrasion. Meteoric abrasion
seems to be the most universal performer in the
great work of denudation. Besides, it is not merely
a surface-worker, as its influence can be found at a
considerable depth below the surface. But extreme
subeerialists would make their favourite agencies do
an enormous quantity of work; and to prove these
theories they base their calculations on the fallacy,
" that all the surface of the ground is being more
or less denuded." This, however, is contrary to fact.
In tropical regions there must be an enormous
amount of denudation, as the hot winds and sun
parch up the surface, forming great thicknesses of
debris, to be carried away by torrents during the
subsequent rains. Still, even in those climes,

70 THE DENUDANTS, OR CARVERS OF THE

denudation does not affect the whole area, as miles
are covered with jungle and forest, sure protectors of
the surface. In alpine and arctic regions the ever-
lasting snow and ice act in a similar manner, and it
is questionable if, in the temperate regions, meteoric
abrasion is able to gradually denude even half the
surface exposed; for in damp districts, undoubtedly,
it would naturally act more as a preserver than a
destroyer. This is well exemplified in many moun-
tainous mining districts ; for in such localities fuel
is often scarce, and the miners cut, for firing, the
peaty surface soil that has clothed the mountain and
preserved it from denudation ; consequently the rain
and other agencies act upon it for a season, cutting
the surface into small ridges and hollows. Never-
theless this does not last long, as the dampness of
the climate soon clothes it afresh with a peaty gar-
ment, and thereby effectually preserves it. In a
district occupied by miners, all the different stages
can be observed : the places from which turf has
not yet been cut, where there has been no denudation ;
the spots newly bereft of turf, where denudation is at
work; and the old turf- bogs where the mountain is
again covered with a thin coat of peat.

A group of table-topped hills, capped by peat and
bounded by steep escarpments, is a good illustration,
showing the contrast between the destroying and
preserving powers of meteoric influences. First the

EARTH'S SURFACE — METEORIC ABRASION. 71

original mass, by denudation of some kind or another,
would seem to have been planed into a flowing,
gradually undulating table land, with gently sloping
sides. Subsequently, by one or other of the kinds of
denudation, or, what is more probable, by two or more
combined, valleys and ravines were cut traversing
the table land in various directions, and forming the
individual hills. When meteoric abrasion began to
work by itself, or a short time afterwards, peat must
have begun to grow on the hill-tops, which effectually
prevented them from being denuded; therefore those
powers could only act in the valleys and ravines, on
the sides of which they formed steep slopes, crowned
by perpendicular escarpments usually a few feet
higher than the thickness of the envelope of peat.
The deposit under the peat is generally the remains
of the original surface drift of the ancient undulating
table-land, and as the covering of peat now protects
its surface, meteoric abrasion works in sideways,
undermining the peat, which consequently topples
over in large pieces when its weight opens the joints.
As the waste thus proceeds both vertically and hori-
zontally, the area of the flat summits must decrease,
although most slowly. Favourable circumstances
will much accelerate the horizontal denudation,
such as in some districts continuous and prevalent
winds from certain points of the compass ; these
rapidly undermine the peat ; consequently on such

72

sides of the hills the slopes are much more gradual
than on those sheltered from the wind.

In cultivated districts, where the valleys are
inhabited and tilled, the protected area of the whole
surface must gradually diminish ; for, as the valleys
widen, the quantity of tillage is increased. But in
wild districts, where nature still reigns, what is
taken from the protected summit has an equivalent
returned in the valleys ; for when the latter have
become wide enough, peat forms there also, which,
once it has established itself, rapidly grows not only
on the flat, but also creeps up the slopes ; so that
eventually there is only a small fringe round the
edge of the table-topped summit which can be acted
on by the denuding forces.

In moist climates, not only on mountains, but also
on low lands (if uncultivated), unless drained
naturally or artificially, peat will grow and defy
denudation. Even in cultivated tracts, when the
land is under grass and not in tillage, denudation
cart have very little effect. This is well illustrated
when a section is opened down a hill-slope that has
been for a long time grass land, more especially if it
merges at the bottom into a boggy flat. In this
instance it will be found that there is scarcely any
difference between the thickness of the surface soil
at the summit and base of the hill ; while the peat
from the flat has been gradually encroaching on the

EARTH'S SURFACE — METEORIC ABRASION. 73

grass land and creeping up the hill. On the other
hand, if a section is cut down a hill similarly cir-
cumstanced, except that it has been tilled for a con-
siderable time, the results will be different, and the
denudation quite apparent ; for the surface soil will
be much reduced in thickness on the slope and
summit, it being carried down the hill, and even
found overlapping and lying on the peat in the flat
below. Such a section will also give a record of the
number of times and periods the hill has been in
tillage and under grass ; for the peat and surface soil
at the base of the slope will be found intercalated
according to the number and length of the times the
hill was exposed to the denuding influences. It may
be said, that although meteoric abrasion does not
denude the surface of the grass land, yet the water
percolating through the soil increases its depth by
gradually rotting the subsoil. This also seems to
be disproved, as it is not of uncommon occurrence,
when draining grass land formerly tilled, to find
lying on the surface of the subsoil the old sods.
This could not be the case if the atmospheric influences
had the power of increasing underneath the surface
soil of grass land. Different authorities have shown
that in some localities " stones grow on the surface;"
that is, the surface of some grass land gradually
becomes covered with stones. This, however, is only
the exception to the general rule, and in moist climates

<4 THE DENUDANTS, OR CARVERS OF THE

can never occur, except in places that are naturally
subjected to extreme drainage ; such as chalk hills, a
country over cavernous limestone, a porous sandstone,
or the like. Calcareous rocks are, in a great measure,
chemically formed, and are more susceptible than
other rocks ; consequently they more readily suc-
cumb to meteoric abrasion, the carbonate of lime
being carried off in solution, while only the insoluble
parts, such as flint, chert, and clayey matter remain.
Besides, during warm weather such lands will be
scorched and burned by the sun, thus forming dust
to be carried away by wind or rain.

Engineers are well aware of the protecting power
of grass, and they grow it on the slopes of their
railway cuttings and embankments, by which means
all denudation is stopped in two or three years ;
after which the surface is added to by the growth
and decay of vegetation, and the work of earthworms
and other soil-producing animals.

Meteoric abrasion can perform a vast amount of
work in tropical climates, as pointed out in South
America by Agassiz, and in Abyssinia by Blandford
in his sketch of its geology. It should, however, be
remembered that meteoric abrasion is most active
in such climates, and that these, in by-gone ages,
could only have existed on limited portions of the
surface of the earth : yet, if we look back into the
records of the past, we find among the Laurentian,

EARTH'S SURFACE — METEORIC ABRASION. 75

the Hnronian or Cambrian, the Cambro-Silurian, the
Silurian, the Carboniferous, and many of the newer
formations, that conglomerates and such accumula-
tions are not uncommon ; while in places they are so
massive and so frequent as to be characteristic of
geological groups. Meteoric abrasion could not have
formed such rocks ; glacial action may have had some-
thing to do with them ; but prior to their being deposited
as we now find them, the fragments and blocks of
which they are formed must have been tossed and rolled
about by the sea or some other large accumulation
of water. At the present day, in places on the coast of
our own little islands, we can study deposits accumu-
lating, that are identical in character with such rocks.
In the tropics the principal rocks that are being
formed by meteoric abrasion, are made up of more
or less fine materials, disintegrated by extreme heat,
and subsequently carried away by wind, or rain and
rivers, to be deposited in lakes or seas.

If we look into the present conditions of Ireland it is
apparent that the growth of soil, except on the coast-
lines, must equal, if it does not exceed, the denuda-
tion by meteoric denudation. On the upper portions
of all but a few of the limestone hills, an envelope of
peat is growing which is yearly increasing, while two-
thirds of the lowlands are in a similar condition. Of
the rest of the country a half at least is under grass-
land or wood; consequently very little denudation can

76 THE DENUDANTS, OR CARVERS OF THE

take place, except the small erosion that is effected
on the banks of streams, rivers, and lakes. Further-
more, most of the detritus carried down from the
uplands lodges on the lowlands, so that only a small
portion of the particles denuded on lands bordering
the coast-line, can be carried out and deposited in the
sea. It may be also pointed out that the present
conditions of this island are not more favourable
than those last preceding; as it is known, from
geological and historical records, that in ages past
the country was a vast forest.

The principal work of meteoric abrasion is to
disintegrate rock surfaces, thus preparing matter to
be carried away by wind, rain, rivers, ice, and the sea.
Sometimes, however, it quarries out masses, as
alternations of heat and cold will open cracks and
joints in rocks. These may become filled with wedges
of water or ice, and such wedges will shift and dis-
place masses of matter ; but, strictly speaking, such a
denudation is not solely due to meteoric abrasion, as
without the cracks resulting from the contraction of
the rocks the denudant could not have quarried the
rocks. Our former colleague, Prof. T. M. Hughes,
of Cambridge, thus describes the denudation of the
cliffs at Sheppy, Kent, England : —

" In the hot weather the surface of the ground is
cracked from the shrinkage of the clay, and the
cracks are seen along the highest ground as gaping

EARTH'S SURFACE — METEORIC ABRASION. 77

fissures about six inches across, and many yards in
length and depth. When the rain falls, it finds its way
into these, and softens the clay at the bottom. If
the crack is near the cliff the half detached mass slips
down to the shore below." 1 Mr A. Geikie, F.R.S., in
his description of the formation of a valley or ravine, has
to acknowledge the necessity of the shrinkage fissures ;
for while writing of the action of springs, he states
that the water percolates through " the joints and
fissures of the rocks." Similarly, when describing
frost action, the necessary assistance of joints and
fissures is mentioned ; and in the description of
the denudation of a rock to form a cliff, there is the
following : — " There is no long escarpment or cliff of
such materials which is not traversed with joints,
faults, or other divisional planes, that serve as
subterranean channels for the water."2 So also has
our colleague, Mr J. C. Ward, when writing of the
scenery of the Lake District, England ; as he says of
the weathering of the hills over Derwentwater : —
" Numerous irregular joints and fissures assist in the
work, and hence the craggy hill-sides."

The sun opens cracks and other shrinkage fissures ;
and without these, as we have pointed out so often,
none of the denudants can work ; yet all breaks of

1 "Mem. Geol. Survey." The Geology of the London Basin. Part
I., p. 387.

2 "Scenery of Scotland," pp. 35-37.

78

this class cannot be placed to the sun's credit, as
some may be due to heat that has its source beneath
the surface of the earth, while many are due to the
movements in the earth's crust.

If the sun acts alone or only in conjunction with
wind, it is a destroyer; but when it is joined with cold
and rain, the effects are modified, as all combined, cause
vegetation which eventually clothes the surface of the
ground with a protecting envelope. Thus it is evident
that the sun ought to accomplish its maximum
amount of denudation in tropical regions ; yet the
amount of work done in the temperate zone must be
considerable, if we may judge from what can be ob-
served in Ireland, as the part the sun has taken in form-
ing its present features is conspicuous. All the hills in
that island, with very few exceptions, have much
longer slopes towards the south than towards the
north. These may have gradual slopes southward,
while northward the cliffs are more or less preci-
pitous; and with scarcely an exception, all the streams
in a mountain group that flow southward have their
source and watershed close to the summit of the
escarpment that bounds the high lands on the
north, so that respectively in all mountain groups
the streams that flow southward are much more con-
siderable than th3 streams that flow northward. This
is apparently due to the rays of the sun acting as a
denudant on those parts of the land that are most

EARTH'S SURFACE — METEORIC ABRASION. 79

under its influence, the rock alternately expanding
and contracting, and thereby disintegrating more
rapidly there than in the land that has a northern
aspect, where the changes in temperature are less.
The different degrees of weathering due to aspect are
very apparent during frost; for at mid-day, if a
bank or cliff looks south, and there is a strong sun,
numerous blocks and fragments will be loosened and
drop away, while in a bank or cliff only a few yards
distant, but having a northern aspect, not even a
fragment will be displaced. This may be studied in
artificial cuttings, such as those for roads — the north
bank yearly weathering away, while years must
elapse before the south side loses the form given it
by the workmen. The effects of the sun's rays may
also be traced in a bog which, during dry weather,
cracks with the heat, as in general the principal
cracks are nearly perpendicular to the sun's rays a
little before noon.

The sun's heat may have opposite effects under
different circumstances. Generally, heat will expand
the matter on which it acts. This, however, may be
sometimes not the case with rocks, as the component
strata of the earth's crust contain more or less
moisture, which the sun's heat evaporates, thus
causing the rocks to contract; but at the same time
there would be at the first an expansion due to the
heating of the moisture prior to its evaporation*

80 THE DENUDANTS, OK CARVERS OF THE

These operations, combined with those of cold, can
break up the hardest rocks into minute particles.

Cold acts both as a destroyer and a preserver. If
matter is dry, it will, as an almost universal rule,
contract by cold ; if, however, it is wet, the moisture
by which it is permeated will freeze and expand.
Cracks opened by heat may be filled with rain or
moisture, cold will freeze and expand the water, and
thus widen the cracks. On the other hand, cold
will change rain into snow, the latter will form an
envelope on the ground, this while it lasts will pre-
vent meteoric abrasion.

Wind is a denudant of no mean power. It works
differently from most of the others, for while they, in
general, carry the debris they form from higher to
lower levels, wind may carry it anywhere, even on to
higher ground. The effects of wind on a perpen-
dicular cliff are unique. Heat, frost, rain, or the sea,
acting on a cliff, will, with rare exceptions, form a
talus at the base, consisting of the detritus that is
constantly falling down. The sea eventually may
indeed carry away the debris ;. but while it is doing
so the upper portion of the cliff will probably be
weathered backward by meteoric denudation, and
it loses the perpendicular character; while heat,
frost, and rain, will change an inland cliff into a
slope, unless there is a lake or river at the bottom of
it. The character of wind denudation, however, is

EARTH'S SURFACE — METEORIC ABRASION. 81

to act evenly on all parts of a cliff, for as fast as the
denudation goes on, the .debris is blown away often
over the top of the cliff, therefore a perpendicular
cliff denuded by wind ought generally to retain its
vertical character.

In Ireland, wind seems to preserve, in a great
measure, the vertical fronts of the huge step-like
cliffs or terraces, for which the barony of Burren,
Co. Clare, is remarkable. Its effect, however, would
be small but for the help received from heat, cold,
and rain, they disintegrating the .rocks and forming a
material easily carried away by wind. Chemical action
must also materially assist by dissolving away large
portions of the rock (limestone). The rain in this
district acts peculiarly, as most, if not all, of the
matter it removes is carried off in solution, little or
no accumulation of surface soil taking place, while the
joints and cracks remain as open fissures. The wind
blowing through these fissures tends to carry all the
insoluble residue away ; but it cannot always accom-
plish this, as, during the summer, plants grow in
many of the cracks, and their foliage prevents the
wind acting.

Wind work can be studied in soft sandstone cliffs,
such as those of New Red Sandstone age on the coast
of Devonshire, where, after a gale, the direction of the
wind can be traced on the face of the cliffs, it form-
ing a miniature " crag and tail " (if it may be so

F

82

called), due to hard particles or pebbles in the rock,
that break the force of the blast and preserve small
portions behind each — the latter tailing off from the
pebbles. Similar wind markings have been observed
on the sides of cuttings in peat, sand, and even
boulder-clay drift, but in the latter it cannot be as
regular, or well marked, on account of the varied
nature of the materials forming the mass ;' but, in
most of these cases, the wind action may be assisted
by the pelting of rain drops. Even in the older
rocks of a much harder nature, conspicuous wind
work has been noted, such as in the slates on the west
coast of Cork and Kerry, where the cleavage planes
are opened, and the smooth surfaces transformed into
a system of knife-edges. Here, however, the wind
is aided by water and heat, the latter opening the
cleavage planes through which the water is driven by
the wind. The sea, also, must aid the work, as this
peculiar weathering was only observed in rocks
within reach of its spray.

Travellers in tropical regions have remarked the
weathering out of the joints and cracks in the rocks,
by which are carved out fantastic pillar-like masses,
or piles like massive cyclopean masonry. This
weathering appears nearly solely due to the combined
action of heat and wind, aided in some cases by rain ;
the first opening out the joints and gradually dis-
integrating the adjoining portions of the rocks,

EARTH'S SURFACE — METEORIC ABRASION. 83

while the wind clears out and carries away the
particles as fast as they are formed; thereby
causing what was once solid cliffs of rock to have a
built appearance. That heat and wind unaided can.
thus work is proved by weathered rocks occurring
in rainless regions. In many places in our own
climate, but more especially those exposed to sea or
mountain blasts, work somewhat similar, except that
it is on a much smaller scale, can be studied.
Wind work evidently has a great deal to do with the
formation of those peculiar rock masses that have
been called by such names as " mushroom "- and
" table-rocks ; " as it drives the rain under them, also
into the crack and joints, to be there contracted and
expanded by heat and cold, which disintegrates the
moistened portions, while subsequently the wind
again acts and carries away the particles. It may be
asked, Why do not these agents act on the whole
surface of the rocks ? So they do, but necessarily the
maximum work must be in the immediate vicinity of
joints and other similar lines, opening them and
weathering away the adjoining parts of the rock.
" Mushroom "-rocks are also formed by wind in con-
junction with the waters of a lake, when the joints or
other lines have very little effect, as the rocks must be
worn away at heights corresponding with the ordinary
summer and winter levels of the waters. Chemical
action must here assist considerably, especially if the

84

rocks are limestone. Similar carvings are said to
be done by the sea, but we have never seen any
examples of the kind, and it would appear necessary,
in order to accomplish it, that the sea should be
tideless.

If mushroom-rocks have been formed by the aid of
the water of a lake or a sea, they will be found on cer-
tain horizons, which is not the case when they are due
to meteoric action. On the hills of Devon and Corn-
wall, England, and the crags of Sligo, Mayo, Galway,
and other places in Ireland, they are numerous, and
it may be seen that, in general, the side open to the
prevailing wind is more rapidly weathered than the
others. Wind action may also scoop out a soft bed
in a cliff, undermining the upper beds. On the
Forum amore mountains, south of the Erriff river
valley, Co. Mayo, there are, in places, outliers of car-
boniferous rocks, and in them are subordinate beds
of friable sandstone. The latter, when exposed to the
south-west, from whence come the most prevalent
winds, are rapidly denuded, the wind driving the
rain into them, to disintegrate them, and afterwards
blowing them away piecemeal, thus undermining
large masses of rock which eventually topple over
and form a rocky detritus.

The moist climate of West Galway diminishes, by
nearly one half, the amount of work the wind can do
in this way ; as, during wet seasons, deposits of blow

EARTH'S SURFACE — METEORIC ABRASION. 85

peat and the like fi]l all minor cracks in the rocks ;
and if there is a succession of wet years, these
accumulations become clothed with vegetation which
protects the joints from denudation. In ordinary
years, during the hot weather, these deposits become
dust and are gradually blown away; but until this is
done, the wind or other denudants cannot act on the
sides and bottoms of the cracks.

In the same county a succession of wet years will
prevent a vast amount of surface denudation by
forming protecting envelopes of peat, and in some
cases a study of their formation is extremely interest-
ing. Many of the ancient marine (?) cliffs have
below them a shingle talus, composed of blocks
ranging from the size of a man's fist to tons in
weight. These tali are probably due to meteoric action
since the land rose, yet many of them are now covered
by a growth of peat, which in places has reached a
depth of eight feet. Any one who has studied the
growth of peat is well aware that it forms and grows
more readily on a non-porous than on a porous sub-
stratum ; large portions of Ireland, as for instance
the mountains of Burren, on account of the porous
nature of the underlying rock, being destitute of bogs.
These shingle beaches on this account ought to be
unable to grow peat ; neither could they do so but
for occasional successions of wet years, during
which the wind and rain carries on to them from

86 THE DENUDANTS, OR CARVERS OF THE

above peaty matter, which remains long enough to be
enveloped with verdure, the growth and decay of
which yearly forms peat, which afterwards creeps
downward, till eventually all the shingle is covered.
That such must be the process is apparent in various
places where, as yet, the work is incomplete..

Rain and rivers by themselves seem incapable of
doing much work, but when combined with the other
denudants, and with cracks or fissures, their effects
are considerable. The connection with cracks, joints,
and the like, is almost ignored by extreme subserialists,
yet they inadvertently admit that there is such.1 An
illustration of the powers of rain and rivers was re-
marked near Draperstown, Co. Londonderry. There,
one of the streams, a head water of the Moyola river,
has its bed partly in drift and partly in a soft friable
conglomerate. At first it might be considered that
the upper part, in the drift, was solely due to river
action ; but on examination it will be found that this
is not the case, as there is a break in the drift,
immediately north, and partly along which the ravine
has been excavated. This stream, during flood, carries
down innumerable blocks and pebbles which appa-
rently ought to rapidly wear away the conglomerate ;
yet this is not the case, for during the ages it has been
at work only a few feet in depth have been excavated,
except in those places where the bed of the stream and

1 See page 77.

87

a break in the strata coincide. Many other striking
examples could be pointed out, especially among the
ice-dressed hills of Galway, Kerry, and Cork,
where streams have run over polished, scratched, and
etched surfaces of rock for ages without having been
able to obliterate the ice-marks.

It has been shown already how rain forms, in the
west of Ireland, a protecting envelope of peat which
stops denudation ; and not only there, but also over a
large portion of Ireland, the moisture of the atmosphere
has a very similar effect; a considerable portion of
the country having a greater or less coating of peat.

Chemical action, although an assistant to the other
destroyers, may also be, in an indirect way, a preserver,
as it disintegrates rocks and forms soil in which plants
grow and eventually form a protective envelope.

We have now given short general descriptions of
the work capable of being done by the different
denudants, and have pointed out that each, indivi-
dually, can accomplish very little ; but if two or more
are combined the work may go on much more rapidly,
while all work most efficiently when assisted by
joints, cracks, and other shrinkage fissures that
facilitate the disintegration and quarrying of rock
masses. Hereafter, when describing the various
features of the earth's surface, we will have to refer
to these different denudants, and occasionally may
have to describe their work more minutely.

CHAPTER VII.

THE RELATIONS BETWEEN FAULTS, OPEN JOINTS, AND
THE FORMATION OF VALLEYS.

BUT for the existence of faults, joints, and other shrink-
age fissures, very few, if any, valleys could have ac-
quired their present form. Those that could be formed
without their aid are valleys due solely to the strata
being bent into synclinal curves. Such valleys may
exist, but they are of very small extent and of rare
occurrence, on account of the operations which have
formed the features of the earth's surface. Prof.
Le Conte's description of the causes to which are
aue the elevation of mountains may be thus epitom-
ised.1 Off a shore line masses of sediment gradually
accumulate, and their weight causes a slow subsidence ;
but when the accumulation of sediment becomes of
sufficient thickness there follows a rise of the geo-
isotherms, and an invasion of the sediments by the
interior heat of the earth. A temperature of 800° is
sufficient to produce, not only metamorphism, but

i "Formation of the Features of the Earth's Surface." The
American Journal of Science and Art. Third Series. Vol. iv., pp.
460, et seq.

89

aqueo-igneous pastiness, or even complete aqueo-
igneous fusion. Finally, this softening determines a
line of yielding to horizontal pressure; consequently,
as the interior of the earth contracts and the shell is
crushed up, the upswelling takes place in these lines.
The enormous folding of the strata which must occur
in the formation of mountains by lateral thrust
would, of necessity, produce fractures at right angles
to the direction of the thrust, and the walls of such
fractures would often slip under the influence of
gravity, or else might be pushed one over the other
by the sheer force of the horizontal thrust, thus form-
ing the different kinds of faults ; the common kind
in which the hanging wall has gone down along
the foot wall, and the uncommon kind generally
found only in strongly folded strata, in which the
hanging wall has been pushed upwards.

Such breaks and fractures as those mentioned by
Le Conte must form lines of weakness and of
shattered strata ready to be removed by the first
denudant that may act upon them ; while on account
of the sheer force of the horizontal thrust, few or no
synclinal curves could come up to the surface un-
broken, and therefore unmodified, and form valleys
solely due to the trough of a synclinal curve.

It may be said that protrusions of irruptive rocks
are capable of forming " intercolline spaces " (Lyell),
or valleys between protruded hills. Such hills also,

90 THE RELATIONS BETWEEN FAULTS, OPEN JOINTS,

however, would be indirectly due to cracks, as with-
out breaks, through which the matter could reach
the surface, we would have no eruptions.

In some mountain groups, such as that of Dublin
and Wicklow, some of the valleys have an appearance
that at first might lead an observer to imagine that
they had been denuded gradually bit by bit ; but
among other hills, such as those forming the highlands
of Scotland, or the mountainous parts of Galway or
Mayo, it is generally apparent that the valleys are
connected with breaks in the subjacent rocks.

A few valleys seem to have no connection with
lateral breaks ; such valleys, however, are only minor
features, and scarcely deserve the name when com-
pared with the others.

In most straight, or nearly straight, valleys, or in
those formed of a series of straight portions, the con-
nection with the associated breaks is easily traced
out; but in many tortuous valleys it is not so
apparent ; nevertheless, after a little examination, it is
seldom that proof cannot be found that all the different
lines, no matter how irregular, have connections with
breaks, either faults or joints. A ravine which
illustrates this fact occurs on the east slopes of Slieve
Gallion, Co. Londonderry. This glen is most irregular,
and after a casual examination its excavations might
be supposed to be due solely to the influence of rain
and rivers. This, however, is not the case, as the rocks

AND THE FORMATION OF VALLEYS. 91

are traversed by systems of joints: one system (a, a,
fig. 22. PL IV.), parallel to the strike of the beds,
while the other (b, b) is slightly oblique to it. Of
these systems of joint lines the stream (c, d) has
taken advantage, at one time excavating along the
lines of one system, at another time along the lines
of the other ; thus a ravine has been cut apparently
most irregularly, but really systematically. In all
such valleys or ravines the protruding angles will be
more or less modified, or even carried away by
meteoric abrasion, as in many of the Devonshire
valleys, where the relation between the old joints,
openings, and the present valleys, is often very much
obliterated and obscured.

Valleys in such accumulations as glacial-drift, on
account of its irregular composition, are not as uni-
form as rock-valleys ; nevertheless, in most tracts of
country they are inclined to occur in more or less
regular systems, as will be seen by examining the
geological maps of the central plain of Ireland,
essentially a drift country, where, in the different
areas, the long narrow bogs, the stream-courses and
minor valley-systems, usually have more or less par-
allel bearings.

In most countries it would seem as if the main
valleys were formed in the rocks prior to the drift
period, during which they were wholly or partially
filled, while subsequently they have been more or

92 THE RELATIONS BETWEEN FAULTS, OPEN JOINTS,

less re-excavated. Dana suggests1 that large rivers
may have flowed during all the glacial period in the
valleys under the ice-sheets, which appears highly
prohable, in which case many of the present valleys
may never have been occupied by drift. Or even if
such rivers did not previously exist, after the ice
began to disappear the valley would be kept clear, as,
" sooner or later, the water from the melting ice,
descending through the crevasses or other openings,
would have made streams in all the valleys, even
those now dry." " The melting would have gone
forward with increasing haste as -the thickness of
the ice lessened ; and all the streams would thereby
have been flooded far beyond modern experience, and
consequently the work of transportation and deposi-
tion would have been vastly accelerated."

In the country lying about the junctions of the
Nore, the Barrow, and the Suir (parts of the Cos. Car-
low, Kilkenny, Waterford, and Wexford), there are
many deep, narrow, and for the most part, " rock-
valleys," they having been evidently formed in the
rock of the country, their slopes being in nearly all
cases meteoric drift, due to subsequent weathering of
their cliffs.2 Glenmore, the valley by which the

i American Journal of Science and Arts. Third Series. Yol. v.,
p. 200.

a When the base of a cliff has been deserted by the sea, it is gradu-
ally modified into a slope. Prior to the year 1846, the north portion
of the estuary of Wexford Harbour was bounded on the north by

AND THE FORMATION OF VALLEYS. 93

road from Ross to Waterford runs, evidently con-
sisted at first of various straight lines joining into
one another ; the top of the southward escarpment
still in a great measure showing their old directions,
while the bottom of the slopes, joining into the
river alluvium, forms more or less regular curves.
At each alteration in the bearing of the valley there
is a more or less well-marked lateral valley, showing
that the changes in direction are due to transverse
breaks, probably lines of fault ; but on account of the
depth of the meteoric drift this could not be proved ;
but in the valleys of the Barrow and associated
rivers, such relations are quite apparent.

Various changes in the level of S.E. Ireland have
taken place in very recent times, the last having
been a rise of from five to ten feet, by which the
land acquired its present elevation.

Before this change the tide in the estuaries of the

drift cliffs, averaging from 20 to 40 feet in height, while in or about
that year the sea was cut off from them, when the " North mud-lands "
were reclaimed. Now (1873) the cliffs have changed more or less into
slopes. In a few places this has been done artificially for agricultural
purposes, in sandy portions rabbits have materially assisted in the
work ; but in general the process consists of the formation of small
landslips, associated with ordinary meteoric waste. In some places
where the drift is a sand and associated with springs, small bays are
being formed in the line of escarpment, the sand during winter being
carried out in large quantities on to the flat. This work has been
accomplished in twenty-five years. Rock cliffs, under ordinary cir-
cumstances, will also be modified into slopes; these, however, may
take centuries, instead of years, to undergo appreciable change.

94

Barrow, the Suir, and the Nore, rose more than it
does now, and the bases of the marginal cliffs were
awash and gradually being denuded. Since the land
has risen, flats or strands have, in most places,
accumulated along the sides, so that now it is only
in a few places the sea can reach the base of the
cliffs ; therefore they are gradually losing their former
perpendicularity. At the same time meteoric abrasion
has not acted on them as extensively as on such as
those in Glenmore, which have been long exposed to
its action ; therefore their geology can be studied and
understood. From them we learn that the changes in
the direction of the river valleys are due to transverse
breaks joining into, or crossing, the breaks along
which the valleys ran, and that most of these lines
of breaks are also faults or displacements, some being
much older than the others. It is quite evident that
some of the faults are pre- carboniferous and others
post-carboniferous ; but whether any of the latter are
post-glacial has not as yet been proved, principally
on account of the general absence of glacial accumu-
lations from the valleys. It is, however, probable that
some of them may be of the latter age, as recent dis-
placements have been proved to be not uncommon in
the surface accumulations occurring on the country to
the eastward.

Valleys often occur along the axis of an anticlinal
curve. This at first may appear remarkable, but on

AND THE FORMATION OF VALLEYS. . 95

consideration it is evidently a natural position, as
when the strata were folded up tension would form
open breaks thereabouts. The upper rocks in a
synclinal trough may be wedged and compressed one
against another, but the upper rocks on an anticlinal
are liable to be separated one from another by stretch-
ing, and broken up by the joint-lines opening, leaving
the rock more or less loosened, and ready to be
carried away by any denudant, whether it be a river,
ice, or the sea. In some cases, however, there is
probably less material carried away than might be
supposed ; for if we take a given length of horizontal
strata and bend it into an anticlinal curve, the[upper-
most beds, under some circumstances, must either
stretch or break ; and if the latter, a V-shaped valley
would form (fig. 14, PI. II.), prior to any denuda-
tion having taken place. The horizontal width of
the valley at the top, b, being nearly equal to twice
the versed sine, to radius ab, of the angle formed
between the bed ab and the horizontal line at the
bottom of the valley ; (fig. 23, PI. IY. horizontal
width = 2 db = 2 versed sine A, to radius ab.)

The folding of strata is worthy of study. If the
strata are thin and each bed is capable of moving
every way, over and under the associated beds, such
strata may be bent up sharply without fracture, the
only effect, apparently, being a little tension above and
compression below on each individual bed. Excellent

96 THE RELATIONS BETWEEN FAULTS, OPEN JOINTS,

examples of such crumpled-up beds may be studied
on the coast of Kerry, in the neighbourhood of
Valentia, but especially in the cliffs bounding the
gut north-west of the hill called Knocknadober,
where some of the folds are right angles, others
inverted acute angles. Strata when folded either
regularly or irregularly, under horizontal compression,
need have no open fissures, if quite free to slide on
each other, as the material in excess in the trough of
the synclinal curves would be pressed up on to the
anticlinals. In nature, however, the compression is
not truly horizontal, the thrust being due to the
shrinkage of the interior of the earth, which crushes
and breaks up the solid crust, causing not only an
horizontal thrust, but also a forcing up of matter
from below, so that in many anticlinal curves we
'find the oldest rocks forming the highest ground, and
in such cases it appears not improbable that the
higher beds have slid down the lower ; or rather more
correctly, that the lower beds have been slipped up
from under the higher. Some seem to deny that such a
slipping could take place, or consider that the slips
must be so small that they are nearly unobservable,
and could not have affected the present features of
the earth's surface. They seem, however, to forget
that even if the angle of dip was only a few degrees
and the slip a few inches in a mile, that in twenty or
thirty miles the slip would be considerable. There

AND THE FOEMATION OF VALLEYS. 97

is also the lateral contraction to be taken into
account, as some of the strata are seen to shrink more
than others, and consequently to add to the width of
the valleys.

In many places there are long, narrow valleys or
gorges, that appear to be in a great measure due to
the contraction of the rocks along lines of fault or
breaks ; these often form marked features. In the
mountainous portions of Scotland and Ireland some
of these lines of breaks and faults appear to be post-
glacial, as the rocks forming their sides are not ice-
dressed ; besides, no part of the ravines formed by
them is occupied by moraine or boulder-clay drifts,
and if their line crosses an accumulation of drift,
there is either a marked hollow or a displacement of
the drift, the latter often being higher on one side
than the other. In Ireland this is well exemplified
in the counties of Tyrone and Londonderry, where in
numerous places the original sheet of boulder-clay
drift, or Till, as it is called in Ulster, has been broken
up by recent breaks, generally faults ; the original
fissures, however, have been subsequently modified,
in some cases by water, probably during the " Esker
sea " period, but in others they seem only to have
been affected by meteoric action.

In "West Galway and Mayo, narrow fissures run-
ning along lines of faults and breaks form conspi-
cuous features in places not only among the hills,

G

98 THE RELATIONS BETWEEN FAULTS, OPEN JOINTS,

but also in the low country; a marked example
extending from Clifden to Cleggan Bay, tins being in
places over 100 feet deep, and not more than 30 feet
wide.

Deep maums, or connecting mountain-gaps or
passes, frequently cross the hills ; two remarkable
ones being those of Salrock and Maumturk, the
latter giving its name to the mountain range which
it crosses.1

In the counties of Kerry and Cork are long, straight,
narrow, more or less regular and deep fissures tra-
versing the hills, which give a marked character to
the country. Some of these evidently are pre-glacial,
as the rocks bounding them are dressed, grooved, pol-
ished, and etched; but others, such as those stretch-
ing across the hills in the neighbourhood of Kilma-
killogue Harbour, appear to be post-glacial, while good
examples of some of the ice-dressed fissures occur
in the vicinity of Mount Gabriel, Schull, Cork. Very
large examples of these fissures occur, in places
cutting down to the base of mountain ranges, and
often diverting the water from one longitudinal
valley into another. These, however, will hereafter
be mentioned when speaking of the valleys of S.W.
Ireland, and at the present we will only draw atten-

1 In the Salrock Pass there seems to have been a fault long prior to
the glacial period ; while subsequent to it there appears to have been
another movement along the old line of break.

AND THE FORMATION OF VALLEYS. 99

tion to the passes through the ridge south of the
valley of the Bearhaven mines, and Ballydonegan
Bay, the ridge having an average height of about
750 feet, while the nearly level floors of the passes
are about 30 feet above the sea, and a parallel pass,
a little farther west, is occupied by the strait that
separates Dursey Island from the mainland.

If valleys are not connected with breaks in the
underlying rocks, how is it that they occur, in
regular systems, over large tracts of country ?
Examine any, but especially a contoured map of
Ireland, and it will be seen that the outlines —
river- valleys, lake-basins, and bays — occur in systems,
the general bearing of which may be indicated by
lines. If such systems are not caused by breaks in
the subjacent rocks, they must be due to chance, an
alternative that even the most sceptical among the
subserialists could scarcely insist on. From the map
of Ireland, it will be learned that the most con-
spicuous system is an east and west one, that forms
nearly parallel features ; two lines stretching across
the island, respectively from Gal way to Dublin Bay,
and from Clew to Dundalk Bays ; while to the north
are other nearly parallel breaks that only extend
eastward as far as the nearly north-and-south valley
in which Lough Neagh is situated ; while to the south-
ward a break runs along the valley of the Lower Shan-
non, and from that to the nearly north-and-south valley

100 THE RELATIONS BETWEEN FAULTS, OPEN JOINTS,

occupied by the Barrow ; it can even be traced as far
as Arklow, but the eastern extension does not form
a conspicuous feature. Further south, from Dingle
.Bay to Dungarvan, is another valley, that of the
Blackwater, along which, as far east as Mallow, a
large fault is conspicuous.

Between these systems there are others that run
in more or less parallel lines. In some these lines
have an easting from north, in others a westing, while
between these there may be other systems extending
more or less east and west. In a few places, especially
if the rocks are ancient or metamorphosed, such as to
the south-east (Wicklow and Wexford), to the north-
west (Gal way and Mayo, also in Donegal), and to
the north-east, there are limited tracts having
minor systems peculiar to themselves ; however, the
principal lines in the last named extend into the
south-west part of Scotland. The connection between
the joints, breaks, valleys, and lake-basins of West
Galway will be described hereafter in detail, as also
those of S.W. Cork, where, although the rocks are
not of very ancient date (Carboniferous), there
are special systems of master joints, breaks, and
faults.

North of the fault (Blackwater valley fault) that
has been proved in the valley that extends from
Dingle Bay to Dungarvan Harbour, ten large faults,
or systems of faults, have been proved and traced,

AND THE FORMATION OF VALLEYS. 101

all of which are connected with more or less marked
features in the ground, and have a general paral-
lelism to one another — 1st, The Slievenamuck fault,
bounding the hills, so named, on the N.N.W. ; this
crosses the slope of the hill, and in general does not
form a very marked feature ; 2d, The Knockfearna
fault, on the N.N.W. of the range of hills of which this
peak is the highest summit ; 3d, A fault in the valley
of the Shannon, that has been traced from Bunratty
to Silvermines, and probably extends to Koscrea ; 4th,
The Formoyle fault, connected with the valley in the
centre of Slieve Bernagh; 5th, The ScarrifT valley
faults ; 6th, The Cloonnagro and Corra valley fault ;
7th, The Lough Atorick valley fault; 8th, The
Derrybrien valley fault ; 9th, The Owenaglanna and
Boleyneendorrish valley fault; and 10th, 'The Dalys-
town river valley fault.

In the valley between Dingle and Dungarvan, a
nearly east-and-west fault has been proved from
Dingle Bay to Mallow, and a branch of it probably
extends to Dungarvan, but the main fault from Mallow
goes nearly E.KE. past Mitchelstown ; this part is
nearly parallel to the faults just enumerated. It is a
downthrow to the northward, as are also Nos. 1, 2, and
3, while Nos. 4, 5, 6, 7, and 8 are downthrows to the
southward, but 9 and 10 have downward throws to
the northward. These ten faults are of Post-Car-
boniferous age, and on account of their parallelism,

102 THE RELATIONS BETWEEN FAULTS, OPEN JOINTS,

they, and others that could not be worked out, pro-
bably belong to one system, and were formed simul-
taneously. Nos. 5 to 10 are connected with the
group of hills called Slieve Aughta, and the relations
between them and the features of the ground have
been carefully worked out, as will appear from the
following : —

In Slieve Aughta there is only one large north-
and-south val]ey, that of Lough Graney ; but the
east-and-west valleys are numerous, and lines of
fault have been proved to occur in each. The latter
valleys can be traced from the limestone country on
the west to the limestone country at Lough Derg,
while the faults could only be proved to have shifted
the beds in parts of them.

The series of faults seen in this district are made
much clearer by the presence of different kinds
of rocks now in juxtaposition, although they were
originally several hundred feet asun.der; the dark-
blue limestone and the yellow and red Old Eed
rocks occurring on one side of the fault, while
the gray and green Silurian rocks are found on the
other.

In places, some of what are here considered faults
might possibly only be Silurian cliffs, at the base of
which the Old Red sandstone and limestones were
deposited, as the rocks strike with the line of fault ;
this is more especially the case with the Cloonnagro

AND THE FORMATION OF VALLEYS. 103

and Corra fault. But that they are really lines of
dislocation seems probable, as there are so many of
them in nearly parallel lines ; also the basal beds of
the Old Red on the upthrow and downthrow sides
are similar, which would scarcely be the case if they
were lines of cliffs.

Bounding the south of Slieve Aughta is the
Scar riff valley, which separates it from the mountain
group called Slieve Bernagh, which lies to the south.
This valley has at least one accompanying fault
which bounds it on the north, and seems to run
from Feakle Lower, to Mount Shannon. The lime-
stone and Silurians are brought together a little east
of a hamlet called Coolcoosaun. A mile and a half
S.E. of Feakle the most westerly traces of this fault
were remarked. From this it can be traced to Cool-
coosaun. On the east it seems to extend to Lough
Derg, but no positive proofs were seen farther than
the Bow River.

The second valley can be traced from Lough
Blarnagh to Lough Ea, where it crosses into the
Lough Graney basin, and down the Lough Ea or
Cahir River to Lough Graney, from whence it runs
along the Corra and Derrygoolin Rivers, coming out
of the Lough Graney basin on the north of Ardeven.
Its fault has been traced from near Maghera Lough
to Ardeven — The Cloonnagro and Corra fault above
mentioned. From the Maghera River towards the

104 THE RELATIONS BETWEEN FAULTS, OPEN JOINTS,

east this fault can be seen in various places, especi-
ally at the village of Cloonnagro. It could not be
traced across the Lough Graney valley, as the break
of this valley probably shifts it, but it occurs again
in the Corra River valley.

A third valley runs from the road from Gort to
Tulla, along the Hollymount Eiver to Loughnagil-
kagh, on the east of which it crosses the watershed
into the catchment basin of Lough Graney, and
proceeds down the Drumandoora River to the Lough
Graney valley, and from thence along the Bleach and
Woodford Rivers to Woodford, crossing out of the
Lough Graney basin a mile and a half N.E. of Lough
Atorick. Its accompanying fault lies a little to the
north, and has been proved from near Carheeny
Lough, by Lannaght, to Corlea Bridge, and from
where the valley ends at Woodford to Lough Derg;
but between Corlea and Woodford it was not
remarked, as the country is covered with either bog
or drift. At Corlea the Carboniferous limestone is
brought down against the Silurians. Near Wood-
ford the limestone and sandstone are thrown against
one another. On the shores of Lough Derg, near the
house called The Lodge, four miles east of Woodford,
this fault brings down the unstra tilled against the
stratified portion of the Lower Limestone. From Corlea
to Carheeny the fault is well marked, dividing into
two branches on the west of the village of Lannaght.

AND THE FORMATION OF VALLEYS. 105

From this valley, near Lough Atorick, there seems
to be a branch fault running toward the east, north
of the hill called Tullymore, past Drummin and
Boleymore, into the bog bounding Lough Derg at
Spa Island. This fault could not positively be proved,
but it seems to shift the rock N.W. of Oghilly
House considerably towards the east, while the
wells near the shore of Lough Derg are probably
due to it.

The fourth of these valleys extends from Lough
Cooter, along the Owendalulleegh River, to Marble
Hill. In this a fault has been traced from Lough
Cooter to near Marble Hill. We have called this
The Derrybrien fault, as it seems to have its greatest
throw in Derrybrien valley, immediately south of the
hamlet called Derrylaur, eight miles east of Gort,
where it brings down the limestone against the
Silurians. In the same valley, at Chevy Chase,
five miles S.E. of Gort, its throw is also consider-
able, as there the limestone is now in juxtaposition
either with the Silurian or the basal beds of the Old
Red sandstone.

A fifth valley extends across the mountain group
north of the summit called Cashlaundrumlahan, with
which a fault is connected. We find in the Owena-
glanna River valley Lower Limestone shale, whose
south outcrop could not anywhere be found ; these
rocks probably are bounded on the south by the S.W.

106 THE RELATIONS BETWEEN FAULTS, OPEN JOINTS,

extension of this fault, as farther west, in the
Boleyneendorrish Eiver valley we find an outlier of
Lower Limestone shale, which has been proved to be
bounded on the south by a fault; but the country
on the south of the Owenaglanna River is covered
with a deep drift or bog, and no positive proof of
the westerly extension of the fault was obtained.

The sixth fault in connection with Slieve Aughta
was proved across the low country to the N.E. of
Dalystown, and at the eastern end of the Dalystown
Eiver valley. This, a little on the north of the village
of Tynagh, brings up a tract of Old Eed sandstone,
which forms low hills that are well marked, looking
at them from the south. This fault has been
proved as far as Hearnsbrook on the N.E., and
Dalystown on the S.W., but it probably extends
much further in the latter direction.1

A remarkable north-and-south feature, that is
evidently connected with a fault, is the valley of the
Barrow, in the S.E. of Ireland; another, having a
similar direction, is the valley from Newry to An-
trim, in the N.E. of Ireland ; while there appears to
be also another, although not so well marked, parallel
thereto, extending from Youghal to Thurles, in the
south of the island. These three lines of break seem
to be of comparatively recent age, as they cut through

1 Memoir and Maps, Geol. Survey of Ireland, sheets 115, 116, 124,
125, and 134.

AND THE FORMATION OF VALLEYS. 107

the systems of breaks with which they come in con-
tact, and shift them more or less.

It may also be pointed out that the general
bearings of the lines of coast are all more or less
connected with the systems of lines in the adjoining
portions of the island, as if the lines that induced
the valleys also had an influence on the coast
features.

CHAPTER VIII.

THE LAKE-BASINS OF IAKCONNAUGHT.

IN different mountainous tracts, the relations between
faults, breaks, and lake-basins could be pointed out ;
but at present we will confine ourselves to West Gal-
way, or larconnaught, on account of the opportuni-
ties of observation there afforded, large tracts of the
country being nearly bare rock, or covered with a
thin coat of peat.

In this area lakes are excessively numerous, especi-
ally in the low country between Clifden and Round-
stone; they are also variable in character, yet a
general classification of them may be made under
three heads, namely — 1st, Bog-basins ; 2d, Drift-
basins ; 3d, Rock-basins.

Bog-basins are surrounded by peat, and are locally
called Loughauns or Ponds, and in general have no
surface outlet from them. They are connected with
breaks in the underlying strata, as all are supplied
by springs, to which they are due. The following
must have been the mode of growth : — As the peat
was gradually developed in the country, it could not
grow over these springs, but formed a wall round

THE LAKE-BASINS OF IARCONNAUGHT. 109

them, pounding up the water, and thereby giving rise
to a small lake. When a loughaun is situated on
low ground, there usually is a swamp or morass con-
nected with it ; but if on high ground, or on a water-
shed, as is not uncommon, its margin is well defined,
and generally higher than the surrounding bog. This
high, prominent margin seems due to the spring-
water equalising the temperature during the different
seasons of the year ; therefore, in the frosts of winter
and the extreme heat of summer, when vegetation is
stopped on the rest of the bog, here it is in full
vigour. Usually the springs are perennial, and the
sides of the ponds are perpendicular, or may even
cove in; some, however, are only full in winter or
wet weather, consequently in summer the bog at the
sides weathers and falls in, making the loughaun
more of the nature of a boggy pool. The drainage
from a loughaun is nearly always by soakage through
the surrounding peat ; sometimes, however, it must
be subterranean, probably between the peat and the
underlying strata, while in a few cases a crack has
opened during a dry summer in the surrounding bog,
and been kept open by the stream from the loughaun
flowing through it. From the above description, it
is evident that bog-basins are not due to denudation,
but to a growth of vegetable matter, while indirectly
they are caused by a break or fault in the subjacent
rocks from which the spring issues.

110 THE LAKE-BASINS OF IARCQNNAUGHT.

Drift-basins may be situated in hollows in drift
accumulations, but most of those remarked in larcori-
naught are partly formed of rock and partly of drift ;
the drift occurring as a mass or bar across a hollow
in the rocks, and thereby pounding-in the water.
Some drift-basins situated in low valleys, such as
the basin of Kylemore Lake, appear due to bars and
mounds of sand and gravel that extend across, or
accumulate in, a valley; the ridge and mounds appa-
rently being ancient sea- work. The formation of such
gra.vel accumulation will hereafter be more minutely
described. Another kind of true drift-basin is in-
stanced by that of Bealawaum Lake in the corry
north-east of the summit of Mweelrea; the hollow
apparently having been formed, in a great measure, at
the same time as the drift, as it is probable that such
irregular accumulations of drift are the debris con-
tained in the ice when it finally disappeared.

For the formation of basins partly rock and partly
drift three agents may be suggested, viz., marine,
glacial, and meteoric action.

Marine action may build up a bar across the end
of a narrow bay or estuary, into which a stream
flows ; and such a mound now exists at the east end
of Cleggan Bay (Map, fig. 16, PL III.) This bar
is evidently due to the meeting of the fresh and
salt water; having begun as a shoal that gradually
grew higher and higher by the addition of debris

PLATE

MAP OF BAR AND LAGOON AT EAST END OF CLEGGAN BAY.

Slightly sloping log

MAP OF BAR AND FLAT, GLEN CORBET.

THE LAKE-BASINS OF IARCONNAUGHT. Ill

driven up on to it by the sea, till eventually it be-
came a mound across the end of the bay, forming
behind it a fresh-water lagoon. The remains and
sites of similar bars and lagoons have been observed
in different places in the neighbouring glens, prin-
cipally at about the 350 feet contour-line which is
supposed to mark the margin of the sea during the
" Esker sea " period. The relations between the bar
and lagoon at Cleggan, and the remains in the glens,
will appear from their descriptions.

On the north end of the Cleggan bar the sea acts
with the least force, consequently the embouchure of
the lagoon is there situated; naturally the drain-
age ought to be at or near the centre, where the bay
is deepest, but in that place there is only an under-
drainage when the tide is out. If, however, the land
rose, this drainage, which at present is a soakage
through the sand and gravel, would be continuous, and
gradually increase, till eventually it sapped the bank
and formed an open through it, which the stream
would deepen more and more, till eventually there
was a cut down to the bottom of the gravel mound.
If the gravel had accumulated in a simple bar,
it is probable all the water would be drained out of
the lagoon, and form a more or less level plain ; but
if there had been gravel mounds formed in the ground
behind the bar, the bottom of the lagoon would be
uneven ; and probably, after the water had cut a new

112 THE LAKE-BASINS OF IARCONN AUGHT.

course, there would be one or more small shallow lakes
on the site of the lagoon. That many of the bars
or ridges of gravel found in the valleys of larcon-
naught were once similar to the bar at Cleggan is
evident, as in addition to the bar, the old stream-
course or embouchure is still visible, also the terraces
formed at the margin of the water in the lagoon. The
accompanying map (PL III., fig. 17) represents
the site of one of these ancient lagoons, the gravel
banks being the remains of the ancient bar; there
are also terraces that not only show the limits of the
lagoon, but also the sea margin on both sides of the
valley outside the bar.

In some bays or estuaries similar bars to that at
Cleggan cannot form for various reasons. First, the
stream may have greater power than the tide ; second,
the river may be subject to freshets, and during floods
all the sand that had accumulated will be swept away,
and spread more or less evenly on the bottom of the
bay ; and third, the stream may be so inconsiderable,
that it cannot form a back-water, between which and
the influx of the tide the bar would form. In the
latter case a semi-bar sometimes forms, the conditions
being unfavourable for its extension across the mouth
of the stream, and such a bar occurs as a gravel bank
at the village of Leenaun, Killary Harbour.

It may be said that the streams at present flowing
into the lagoon at Cleggan are too small to have

THE LAKE-BASINS OF lARCONNAUGHT. 113

formed the bar and lagoon. This is probably correct,
as it must be borne in mind that at no very remote
period all the streams and rivers in larconnaught were
larger than they are now, as two or three hundred years
ago most of this area was a forest. Boussingault,
who wrote on this subject, gives facts showing the
effects caused by the cutting down of the forests on
the streams and springs in South America ; further-
more, this fact is so well known on that continent,
that some of the South American governments have
passed laws regulating the felling of timber.1

Other evidence in favour of the larconnaught
streams having been larger than they now are, is
that in different places peat is gradually growing
over and filling up old stream-courses.

If a stream debouches on an open seaboard, a
bar and lagoon may form if the ground is low and
the volume of water discharged is insufficient to sweep
away the sand driven up by the wind and sea. Such
lagoons were remarked on the coast of S.W. Mayo,
but more extensive ones are found in South-east Ire-
land. These, such as that which existed at Kilmore,
County Wexford, are separated from the sea by irre-
gular eskers (anglice, ridges) of more or less fine, often
stratified, sand. Such eskers are evidently, in the first
place, bars formed between the open sea and the
shoal water, which afterwards are augmented by sand-

1 Edinburgh Phi/. Jour. xxiv. (1836), pp. 89-91, and 102, 103.

H

114 THE LAKE-BASINS OF IARCONN AUGHT.

and-shell debris blown up into them by the wind,
each heavy gale forming a new layer, which the
vegetation binds more or less together, and preserves
froin removal by subsequent winds. In some places
the lagoon has become filled with a peaty soil, and
as the south-east of Ireland seems to be gradually
sinking, the sea is nearly imperceptibly moving back
the sand-ridge, so that in places the sand-ridges are
found to have a peaty foundation under them.1

Bars and ridges of gravel or sand like those we
have described, can only form near the end of a bay,
or at the margin of the sea. There are, however, other
accumulations, such as the already-mentioned banks
and mounds of gravel and sand in the valley of Kyle-
more. These would appear to be comparable to the bars
at present forming in straits, or any other place where
two tides or currents meet ; and if the land hereabouts
was lowered 350 feet, the tides would flow and ebb
through the valley of Kylemore, and form similar bars
and mounds to those that at present exist.

That such conditions obtained during the " Esker
sea " period, appear proved by our finding in the
different valleys of larconnaught, and also in Clare,

1 Althougli this coast may be now sinking, it appears not improbable
that a short time since it may have been rising, as part of the ridge
that now margins the mudlauds of Wexford Harbour is said to have
been formerly off the mouth of that haven, and was marked on the
charts as dangerous shoals. The estuaries on this coast deserve a much
more careful examination than has yet been given to them.

THE LAKE-BASINS OF IARCONN AUGHT. 115

Limerick, Kerry, Cork, &c., places miles apart,
terraces that mark the margin of this ancient sea.
These gravelly accumulations are generally associated
with rocks to form the lake-basins ; and in many
valleys after their elevation, rain and rivulets have
cut channels through the bars and banks, thereby
eventually draining the hollows in which lakes at
the first existed; so that now only in a few, where the
cut was not deep enough to drain all the hollows,
do lakes exist. If we examine the Kylemore valley,
we find that its lake once extended considerably fur-
ther up and down the valley, and that the small
lakes there at present were only deeps in the ancient
lake, which the present outfall cannot drain.

The third class of bars are those due to glacial
action. Hooker, Forbes, and other Alpine or Arctic
explorers, have described the moraines which form
across valleys and hollows, also the avalanches and
other debacles of rocks, stones, clay, and mud which
slide down into valleys during thaws, damming up
the drainage, and stopping the original water-courses,
often forming lakes of greater or less dimensions.
Snow drifts may act similarly, as the up-side may
become a sheet of ice, and prior to its melting away
a river or stream may cut a new channel, and desert
its old one. In the mountainous parts of Great
Britain and Ireland, bars of drift, apparently of
moraine origin, or accumulations from successive

116 THE LAKE-BASINS OF IARCONNAUGHT.

avalanches, often extend into valleys. Some of these
must at one time have stretched across the valleys,
ponding up masses of water, and thereby forming lakes.
Now, however, in most cases, the stream-courses
having gradually become deeper and deeper, the bars
have been cut across, and the original drainage of the
valley is restored ; but not in all cases, as, for instance,
Lough Inagh, Connemara, which is separated from
Derryclare Lake by masses of moraine drift, to the
bottom of which the connecting river has not as yet
excavated its channel.

The fourth class of bars are meteoric. Such bars
most writers appear to ignore, yet they often form
marked features, and their formation can in many
places be studied. A bar partly meteoric and partly
lacustrine may be formed when a torrent flows into
a lake and makes a delta, called in Ireland a srah —
i.e., the level land at the inver or mouth of a river or
stream, usually covered during freshets. A srah
forms in a wide lake by the waters during floods
levelling the surface of the detritus as it is brought
down ; but in a narrow lake a bar may form across it,
and if the original embouchure of the lake is after-
wards lowered, two sheets of water form, one with a
higher level than the other, and in Ireland such a
lake is generally called Lough-a-voul or Lough-aw-
woul (anglice, the lake of the two spots).

Other bars may be due to detritus carried down by

THE LAKE-BASINS OF IARCONNAUGHT. 117

a torrent into a flattish part of the valley. As we have
not seen the work of one of these mountain torrents
described, we may attempt it. Mountain torrents
are very erratic in their movements : for years they
may flow in one course, but at any time the old
course may be deserted and a new one excavated. A
newly-excavated torrent-course down a hill-side, has all
the appearance of a more or less deep, artificial trench,
from which the materials excavated had been thrown
in irregular banks or heaps on both sides. At first
the stream takes possession of some sort of break
in the surface soil, whether a crack due to contrac-
tion, a path worn by sheep or cattle, a rut exca-
vated by lightning1 or the falling of a waterspout,
or a» trench cut by man. This it deepens and widens
at the bottom, till eventually, during sudden floods,
the stream forces up large masses of the surface, and
scatters the debris along the banks of the channel ;
or the water may carry some of the lumps along
with it, till caught in one of the narrows of the exca-
vation, when they form a dam. While the dam exists,
the rush of water from above will force all transported
materials, such as stones, turf, and the like, up on
to the banks on both sides. Such dams rarely last
long ; but as they are continually forming and burst-

1 The ruts due to the lightning observed on the hills in larcon-
naught had an appearance very like a regular furrow opened by a
plough.

118 THE LAKE-BASINS OF IARCONN AUGHT.

ing in different places along the excavation, the detritus
carried down is distributed more or less evenly on
each bank, forming piled-up, artificial-looking heaps.
Each stoppage also adds to the force of the torrent,
as the pent-up water, when a dam bursts, rushes down
with increased velocity.

The work done by the same or a similarly circum-
stanced torrent when it reaches a flat would be differ-
ent, as there, instead of excavating a channel, it would
build up a bar extending out from the hill-side, and
in some cases even reaching across a valley, thereby
damming up the drainage, and forming a lake. In
many cases the streams, for reasons somewhat ana-
logous to those just mentioned when describing the
descent of a torrent down a hill-side, will keep on the
top of its bar, and thereby increase its length ; but not
always, as sometimes it will break over to one side or
another; after which, if it breaks over on the upper
side, it will begin to denude away the bar. Remark-
able examples of bars of this class occur at the, Lake
of Geneva, especially on the flanks of the great snow-
hills between Clarens and Yilleneuve, each bar or
mound having the torrent that formed it still flowing
along its summit. Lakes due to the formation of a
meteoric bar across a valley are usually shallow, both
on account of the form of the ground, and also because
the bars are more or less porous ; the sheet of water,
therefore, is seldom considerable, except during heavy

THE LAKE-BASINS OF IARCONNAUGHT. 119

rains, when the supply exceeds the drainage by soak-
age. There is, however, an exception, when one of
these bars forms across the mouth of a corry, a place
in which they are not uncommon, for reasons mentioned
hereafter, while describing the formation of corrys
and their lake-basins.

Other meteoric bars may be due to landslips, as
during dry weather cracks will form in mountain
slopes, whether the drift be meteoric or glacial. If
such cracks run up and down the incline, or perpen-
dicular to the trend of the valley, they only form
channels afterwards to be occupied by streams ; but
if they are transverse — that is, rudely parallel to the
lower part of the valley — water, after rain, will collect
in them, and finding no egress, will eventually force
out large masses, that slide down to the bottom of the
valley and dam up the drainage. Hooker has de-
scribed such debacles in the Himalayas which are of
considerable magnitude ; but none of those remarked
in West Gralway are very large.

Other bars that have been noted may possibly be
due to avalanches during the time that snow and ice
existed in the hills, as we know that at the present
day, in Alpine regions, avalanches occur in special
places, and by their frequent sliding, accumulate bars
of drift. In other places, lakes may possibly be
formed by beavers' dams. This suggestion, however,
is merely conjectural, and prompted by the form of

120 THE LAKE-BASINS OF IARCONN AUGHT.

some of these lake-basins. Against it is the fact, that
although the beaver is known to have been an in-
habitant of Wales during the historic period, yet we
have been unable to find in the Irish annals any re-
cord of its existence.1

The great characteristic of the larconnaught lakes
are their " rock-basins." Such basins Professor
Ramsay seems to believe have been formed by ice
action, but of this theory Lyell writes, " It appears
. . . that the abrading _action of ice has formed some
mountain tarns and many moraine lakes, but when
it is a question of the origin of larger and deeper
lakes, ... it will probably be found that it has
played a subordinate part in comparison with those
movements by which the changes of level in the
earth's crust are gradually brought about."2

"We, however, would go even further than this
eminent geologist, and suggest that, unaided by the
other great denudants, and also by cracks, fissures,
and faults formed during the movements in the
earth's crust, ice is incapable of eroding out rock-
basins.

In larconnaught, not only is meteoric abrasion

1 There does not appear to be any real native Irish word for beaver.
In O'Reilly's Dictionary we find " Dobkran-leasleatkan, a beaver," but
he seems to have taken this from the Scotch Gaelic, as no mention of
beaver is known in any Irish MS. DoWiran means water-animal, and
leasleathan broad-tailed. The "Welsh for beaver is similar, namely,
" llostlydan," broad tail.

2 " Student's Elements of Geology," p. 164.

THE LAKE-BASINS OF IARCONNAUGHT. 121

going on at the present day, but also, what appears
to be its work in ages long past can be recognised.
Marine denudation has left its records in the raised
gravel-bars and beaches, in the terraces on the hill-
sides, and in the cooms and corrys at similar eleva-
tions, not only in the hills of G-alway, but also in the
hills of Clare, Limerick, Kerry, Cork, and other moun-
tainous places in Ireland, while at the present day
similar work is being accomplished on the coast-lines.
Glaciers are now doing no work ; but that they once
existed is proved by the dressed hummocks and the
planed, grooved, etched, and polished rock surfaces.
It is quite palpable that the rocks of larconnaught
have suffered at successive periods from the disturb-
ances due to the movement in the earth's crust, as
they are not only folded and contorted, but also faulted
and displaced to a very remarkable extent. Some
of the faults must be very ancient, as the " fault-
rock " in them was metamorphosed along with the
associated rocks ; while others are post-glacial, as was
pointed out by our colleague Mr R. Gr. Symes, F.G.S.,
as they displace the ice-formed drift. These last-
mentioned breaks are very instructive; 'for although
they form greater or less hollows, some over 100 feet
deep, and not more than from 10 to 30 feet wide,
yet in general, the horizontal displacement is trifling,
while in some it may be nil, as the same strata at
opposite sides of a ravine may face one another, while

122 THE LAKE-BASINS OF IAKCONNAUGHT.

the cliffs on both sides may be on a similar or nearly
similar level, as if the break had opened or gaped
while no vertical or horizontal movement had taken
place.

The rock lake- basins of larconnaught may be in
corrys or maums,1 or on hill-tops, while others are in
valleys, or in comparatively level plains ; always a con-
nection between them and one or two lines of master-
joints or faults is apparent, which would seem to
suggest that these lines of break, whether faults or
only shrinkage fissures, must have materially assisted
in the formation of rock-basins.

During, and after, the formation of a fissure at the
surface of the earth, unprotected either by water,
ice, or the like, meteoric abrasion would modify it,
forming debris that in part might be carried away by
rain, rivers, or wind. Marine action would act nearly
similarly, if the fissure was lowered and came under
the influence of the sea ; so would also ice, if that
agent was subsequently formed, or if it existed prior
to the development of the fissure; — the traces of
the work of these different denudants are preserved
in the rock-basins, fissures, gorges, and ravines of
larconnaught. Another feature of these rock-basins
is, that all the long stretches coincide with lines of

1 Corry (coire, Celtic, pot or cauldron), a valley having a bowl shape ;
maum (madhm, Celtic, the inside part or hollow of the hand), a connect-
ing mountain gap or pass, the equivalent of col.

THE LAKE-BASINS OF IAKCONNAUGHT. 123

breaks, faults, or other shrinkage fissures, as well as
all the transverse guts and bays. This is exemplified
in the accompanying map of Lough Conga (Map,
fig. 15, PI. II), the lake being specially selected on
account of its outline being so irregular. All the
lake-basins in this country widen or contract in
accordance with the number of faults or joint-lines
which meet or cross in the area occupied by them.
If such lines were numerous, close together, and
crossing one another, a considerable portion of the
rocks would be broken up, and more or less easily
removed, either by ice or sea action ; while if only
one line or two parallel lines existed along which the
force could act, the hollow excavated would be long
and narrow. All these cases are exemplified by
the larconnaught rock lake-basins, some of which
are wide, others long and narrow, many most ir-
regular in outline, while all coincide with the
associated features of the country due to the breaks
and faults in the rocks.

After rocks have been broken up by faults and the
like, marine action in a shallow basin could sweep
or suck out the broken materials ; but in places of
considerable depth it appears incapable of executing
the necessary work. Meteoric abrasion would take
an incredible length of time to do it, as it would first
have to disintegrate the blocks and fragments, while
the detritus would have to be removed by wind, or

124 THE LAKE-BASINS OF IARCONNAUGHT. i

through a subterranean passage by water. An ice-
sheet, however, appears capable of doing the work
more quickly, as it would lift up the blocks and
other detritus and carry them off, whether the hollow
be situated on a hill-top, in a valley, in a maum, in
a corry, or on a flat plain. From this it will appear,
that although it is probable both marine action and
meteoric abrasion may have accomplished a little
work in removing the debris produced by the cracking
and faulting of the rocks, yet the chief worker would
seem to be ice, which would account for rock-basins
being typical of glaciated regions.

After the ice had disappeared from the country
such hollows would become filled with water, and
form lakes. This, however, would require, in all
basins above the sea-level, that the joints and " fault-
rock" should be water-tight, or the subterranean
vent incapable of carrying off the surface supply, or
that drift or other matter should be deposited and
staunch the water-basins. It is quite apparent
that some of the rock-basins in larconnaught have
subterranean passages connected with them, while
others have had them ; but in the latter cases
they have since been closed by a peaty deposit
carried into the lakes by wind, rain, and streams.
There are, however, other rock-basins, that never
were, and probably never will be lakes, the
fault-rock being so loose and incoherent that no

THE LAKE-BASINS OF IAECONNAUGHT. 125

water can remain in them. Examples of these
waterless rock-basins occur on the hills of Errisbeg,
near Roundstone and Lettermore, north of Bally-
nakill Harbour, which respectively are composed of
hornblende-rock and quartz-schist, rocks which, on
account of their hard nature, are not easily broken
small, and consequently are likely to form loose,
open "fault-rock." In places on the low ground
similar rocks also occur. Here, however, rock-basins
are liable to be invaded by peaty matter carried
by wind and streams ; consequently, in many cases,
basins that doubtless once leaked are now water-
tight. Nevertheless, in places there are large tracts
solely drained through subterranean passages.

In these rock-basins, especially those on Errisbeg,
the connection between them and breaks or faults
is very apparent. Some of the latter are evidently
post-glacial, and point out the large vacancies which
may be formed solely by the contraction of the rocks,
and the small quantity of debris that a subsequent
denudant, in such cases, would have to clear out.

CHAPTER IX.

COP.RYS WITH OB WITHOUT LAKE-BASINS.

EMBOSOMED in a corry or coom, a small lake is often
found. Sometimes in a true rock-basin, but more
often in a basin partly rock and partly drift; or even,
as previously mentioned (as in the case of the basin
of Lough Bellawaum), it may be solely drift. To
this subject special attention has been drawn by the
Rev. M. H. Close, M.R.I.A., &c., in a paper, "On
some Corrys and their Rock-basins in Kerry."1

From this memoir it would appear that the author
considers the formation of corrys to be largely due
to ice action. The following is an epitome of his
reasons for coming to this conclusion : —

a. Corrys cannot have been formed by the atmos-
phere, for this agent is now engaged in trying to soften
them away ; nor by the sea, for the following reasons :
—The sea does not seem to be now producing such
features on the S.W. coast of Ireland. The floors of
contiguous corrys are often of very different ele-
vations; while there are no apparent terraces on the
open mountain-sides corresponding with the corry

1 Jour. Roy. Geol. Soc. Ire. New Series. Vol. ii. p, 236.

CORRYS WITH OR WITHOUT LAKE-BASINS. 127

floors. Corrys liave no perceptible preference for
places which were most exposed to the action of the
sea.

b. These hollows are of a different order from the
other shapes of the mountains on which they occur,
which argues a special mode of formation.

c. The rock-basin, when there is one, is an integral
part of the corry, formed along with it, and not sub-
sequently by a different operation.

d. The cauldron-like shape of the corry is just what
we should expect would be superinduced by an agent
formed, moving, and working as a small glacier.

e. These hollows have a decided preference for the
higher mountains.

/. They affect the highest parts of mountains.

g. The majority of them face northerly or easterly.

h. According to Professor Ramsay, the corry is
eminently characteristic of all glacier countries, past
and present.

Notwithstanding this observer's conclusions, an
examination for ourselves has led us to believe that
ice is only a minor agent in the formation of corrys,
they being mainly due to the faulting, jointing, and
dislocation of rock masses, combined with marine
and glacial action, and probably also with meteoric
abrasion. In some corrys the mass of the drift will
be glacial, in others marine, and in a few meteoric ;
and these different drifts could not have accumulated

128 CORRYS WITH OB WITHOUT LAKE-BASINS.

in such places unless the special forces connected
with them respectively had been at work.

In the County Kerry most of the corrys are large
and well-developed, while in West Galway and
Mayo they range from large to small, Glenawough,
in the Formnamore Mountains, being as large and
grand as any in Kerry, while some of those situated
in the Maumturk Hills are mere holes or recesses in
the mountain slopes, some of the smaller being less
in extent than the cooms which are now being
excavated by the Atlantic Ocean at the present day
in the coast cliffs of the neighbourhood.

All the corrys in Galway and Mayo are connected
with breaks or dislocations in the strata, and their
forms have a greater or less regularity in accordance
with the position and number of the lines of breaks.
As there is a similarity between the larger excava-
tion (to which some would confine the term corry)
and the smaller ones, it is quite legitimate to argue
from either to the other ; therefore, as the formation
of cooses on a sea-coast is easily studied, we may de-
scribe their mode of formation.

The north-west coast of the County Galway, near
the mouth of Ballynakill Harbour, is favourably
situated for the excavation, by marine action, of
land-locked cooses, and here, in a short coast-line,
many of them may be noted. Of these, one is large
enough in plan to be classed amongst Mr Close's

CORRYS WITH OR WITHOUT LAKE-BASINS. 129

corrys, while all are being similarly formed, although
many are very diminutive. This coast is dissimilar to
the rest of that of the County Galway, as the cliffs
range from 100 to 400 feet high, while it is not open
to the full force of the Atlantic Ocean, having nearly a
northern aspect, and being subject to a cross current
due to the tides meeting the stream flowing into and
out of the landlocked bays known by the general
name of Ballynakill Harbour ; and, as before pointed
out, the sea acts more vigorously in confined places
than on the open seaboard.

In about half-a-mile of this coast there are seven
cooses now being excavated or scooped out; these
were carefully examined, and the details noted.

In Goose No. 1 there are four breaks in the strata
that have facilitated its excavation — a main-break,
that seems to be also a fault (a, fig. 9, PL I.), along
which the sea at first worked ; it afterwards came
to the cross breaks (£, £, and «Q, when it began to
widen out the interior of the coose.

Coose No. 2. — The sea worked in along two breaks
until it came to two cross breaks, between which the
rock is being excavated.

Coose No. 3. — Here there are two breaks (a and £,
fig. 10, PL I.) diverging from the coast- line along
which the sea could work, and subsequently exca-
vate out the intervening rock. The work has now

130 CORRYS WITH OR WITHOUT LAKE-BASINS.

come to a cross break (<?), and it seems to be going
on more rapidly.

Cooses Nos. 4 and 5 respectively are due to two
breaks that join at a little distance from the original
coast-line. In both cases the sea at first worked
along the breaks, but it is now also cutting out the
intervening mass of rock, slight deeps having been
formed at the junctions of the joints, evidently in
consequence of the broken rock being scooped out by
the back curl of the waves round the masses of rock
that stand at the entrances to the cooses.

Coose No. 6 is an example of a single break (#,
fig. 11, PI. II.) along which the sea is working, and
forming a long wedge-shaped gut.

Coose No. 1 is large, well-marked, and extensive,
being fully as big as many of the Kerry corrys. It
is about 4000 feet in diameter, a size that is greater
than many of the cooms in the larconnaught hills.
The formation of this coose is clearly dependent on
three breaks (#, b, and c, fig. 12, PI. II.), two of
which met at the old coast-line. It may be said
none of these are large enough to be classed as true
corrys. This we allow, but at the same time it is
evident that they are corrys in miniature ; and if the
sea had time enough to work, it would enlarge them
to any size.

Cooses like that represented in No. 6 are not un-
common on coast-lines, while in the hills, cooms of

CORRYS WITH OR WITHOUT LAKE BASINS. 131

a similar shape are frequent, on which account they
are passed over without much notice. Of the other
examples of cooses, if we give due allowance for
subsequent modification by meteoric abrasion, their
counterparts will be found in the cooms among the
larconnaught hills. One thing remarkable about these
cooms in the hills is, that although exposed for cen-
turies to meteoric abrasion, their floors are very similar
to those of the cooses now being formed by the sea.
In the hills, west of Lough Inagh, the floors of the
cooms slope outwards ; south of the Erriff valley they
slope to one side, while in the north part of the
Mweelrea mountains they contain deeps ; but the deeps
in the cooms and those in the cooses, as will hereafter
be stated, are not quite similar. Seemingly the con-
ditions most favourable for the sea excavating a coose
are as follow : — First, The rocks on the coast should
lie nearly horizontal or dip inland. Secondly, The strata
must be traversed by breaks (whether master-joints
or faults) lying oblique to and crossing one another,
also joining into the coast-line. Thirdly, Alterna-
tions of rocks of various hardness or composition ; for
if rocks on a coast are homogeneous or nearly so,
marine action will probably denude the coast in more
or less regular sweeps or open curves. And, fourthly,
cross currents, in the sea, that will form eddies. On
an open seaboard, the denuding force must act more
or less uniformly; not so, however, in partly land-

132 CORRYS WITH OR WITHOUT LAKE-BASINS.

locked bays or among islands, as in such places
there must be cross currents working in irregularly.
The undermining of a cliff cut by two or more oblique
master-joints or faults may also form a coose, as a
large mass may thereby lose its support and slip out
to sea, to be afterwards broken up and dispersed by the
waves. Such cooses, in different stages of formation,
may be observed on various coast-lines ; but all the
cooms among the hills that may have been formed
from the slipping of a mass of rock are not due to
sea action, as springs, or even the wind, may erode
and carry away some weak beds or strata, and thereby
leave unsupported a mass bounded by master-joints
or faults. In such cases, however, the debris of the
mass will be scattered on lower ground, or occur in
the form of a bar or mound, unless carried away by
ice or a river.

Blanford has pointed out that, in tropical climates,
while marine actjon is at a minimum, meteoric abra-
sion is at a maximum ; l the quantity of detritus pro-
duced by the heat, and carried down by rivers into the
sea, forming large alluvial flats, which protect the
coast-lines from marine denudation ; or in places
where such deposits cannot form, coral reefs grow,
fringing the coast, and having a similar effect.

Explorers of arctic regions have taught us that,
in those latitudes, most of the detritus due to atmos-

1 "Geology, Abyssinia," p. 151.

CORRYS WITH OR WITHOUT LAKE-BASINS. 133

pheric influences which is brought down to the sea is
at first left on the " ice-foot," or belt of ice fringing
the coast-line, to be afterwards, when that breaks
up, carried away and deposited in mid-ocean; con-
sequently, in such regions, there can be no natural
breakwater formed, but the coast must be left open
to the full action of the waves and marine currents.
In such places, therefore, marine denudation ought
to be more active than elsewhere.

Let us now consider the temperate zones. Here
all of the denudants do some work; none of them,
however, being at the maximum or minimum of effi-
ciency, as the principal working powers, heat and cold,
under which all act, cannot reach their extreme inten-
sities. There is, however, some little work done by
each, more or less considerable in accordance with the
varied circumstances under which they act. Hence it
would seem that atmospheric influences perform their
maximum of work in tropical climates, and their mini-
mum in arctic regions ; on the other hand, both marine
and ice action accomplish their maximum of work in
arctic regions, and their minimum in the tropics.

Let us now consider the conditions under which
larconnaught formerly existed. Here, as well as over
the whole of the North of Europe, an arctic climate
prevailed at the beginning of the glacial period,
and the efficiency of marine action must have been
considerably greater than at present ; to which add

134 COURTS WITH OR WITHOUT LAKE-BASINS.

that of glacial action, which does not exist there at
present ; and the cooses then formed ought to be much
more extensive, and bounded with higher cliffs, than
those being excavated in the temperate zone at the
present day. We would suggest that the corrys, after
having been in part excavated by marine denudation,
were elevated by the rising of the land out of the
influence of its action, and that afterwards they were
enveloped in snow and ice, and thereby preserved from
"being modified by ordinary meteoric abrasion. Dur-
ing the glacial period, all of these corrys, at no matter
what level, were protected by this envelope against
atmospheric influences ; but as the climate changed,
those on low ground, especially if exposed to warm
winds or the sun's rays, would be subjected to all the
vicissitudes of the atmosphere, which probably altered
and modified their forms, or even obliterated them ;
consequently, while corrys and cooms are numerous
in high lands, in the adjoining low lands only traces
of them can be detected.

In the northern hemisphere the warm winds and
sun's rays would act more on the south and west
slopes of the hills than elsewhere ; consequently, on
the north and east slopes the snow and ice would
remain, preserving the cooms, corrys, and cliffs long
after the south and west sides had been modified and
formed into more or less regular slopes by meteoric
abrasion. That such took place in Ireland is quite

CORRYS WITH OR WITHOUT LAKE-BASINS. 135

evident, as we before pointed out ; for while, as a
general rule, that has few exceptions, the cooms,
corrys, and cliffs are situated on the east and north
sides of mountains, the west and south sides of the
hills are slopes. (See page 78.)

It may also be mentioned in favour of marine action
having partially excavated the corrys, that such fea-
tures occur at distinct elevations. Two or more corrys,
in the vicinity of one another, may have their floors
on different levels, or even in a large corry there may
be two or three cooms at different heights ; but if
the altitude of all the cooms and corrys in a group of
mountains or in separate groups of mountains are com-
pared, they are found to be in systems. In larcon-
naught and South-west Mayo, systems occur at heights
of 250, 350, 470, 650, 750, 1000, 1200, and 1400 feet ;
while in Kerry, from the elevations given by Mr
Close, they seem to be found at elevations of about
450, 750, 1000, 1250, and 1500 feet in altitude. As,
however, there are numerous corrys not mentioned
by this observer, this evidence is not conclusive.1

1 All the groups of hills in West Ireland, from County Sligo to
County Cork, are, as a rule, much more escarped on the north and east
sides than on the south and west. This fact, combined with peculiari-
ties in the drift, led me, on a former occasion, to suggest that, about
the end of the glacial period, there must have existed a strong ocean
current flowing from the N.N.E. to the S.S.W. (" Notes on Some of
the Drift in Ireland," Dublin Quart. Jour. Science, vol. vi. pp. 249, ct
seq.), also that to this current the steeps were due. I would now wish to
slightly modify this suggestion ; for although such a current must have

136 COURTS WITH OR WITHOUT LAKE-BASINS.

Subsequently to the corrys having been in part
formed by marine action, they seem to have been
enlarged and deepened by ice, as ice apparently
would have more power than the sea to form the
rock-basins so often associated with them ; for, as
shown previously, it would be more capable of lift-
ing and carrying away all the blocks loosened in
the breaks, besides raising additional blocks ; for as
the water from the ice froze in the crevices and
cracks, it would loosen and quarry out other blocks,
and raise them up into the influence of the ice-
stream.

Although we are inclined to believe that ice was
the principal agent in excavating out the rock-basins
of the corrys, yet we should point out that water also
is capable of excavating somewhat similar hollows,
and in an arctic sea may have had powers that are
unknown to us of the temperate zone. The forma-
tion of those peculiar cylindrical hollows, often called
" churn-holes," found in some rocks on the sea-
coast, and in river-beds, seems to point to a process
by which the sea might grind out deeps in the floors
of the corrys. " Churn-holes " are not uncommon,
and we find they always occur in rocks containing
nodules, concretions, or some other kind of macula

formed cliffs, yet it is probable that they in part existed prior to the
current, especially at high altitudes, and were preserved from modifica-
tion or obliteration by an envelope of snow and ice, while lower down
marine action was changing the form of the old ground.

CORRYS WITH OR WITHOUT LAKE-BASINS. 137

softer or more easily weathered or removed than
the rest of the rock. Such spots, when exposed by
denudation to atmospheric influence, crack, and
subsequently weather out. Once a hollow is formed,
no matter how small, particles of sand find their
way into it, and these are whirled -round and round,
either by wind or the eddying of water, thereby
deepening and enlarging it. As the hole increases
in size, larger grinders are admitted, and the work
goes on more and more rapidly. If the maculaa are
situated widely apart, as is often the case, the holes
for the most part will be cut symmetrical ; but if the
weak spots are more numerous, one hole may
encroach on another, or, what is not uncommon,
holes may form in the side of one in progress, if the
grinding process exposes to the weather some of
the concealed soft spots. In other cases the
maculae are so numerous that the weathering is
quite irregular, and without marked form. Such are
generally passed over unnoticed, while the remark-
able form of the " churn-holes " always attracts
attention.

Similarly, marine action might be able to excavate
hollows in cooses. The sea, however, in such cases,
could scarcely work as symmetrically ; for while, in
the case just mentioned, the water would begin its
work on the cracks in a more or less regular nodule
or the like, the sea in the coose would be working

138 CORRYS WITH OR WITHOUT LAKE-BASINS.

on a more or less irregular junction of two or more
breaks; but subsequent weathering would modify
the form of the hollow, and make it more bowl-
shaped.

As pointed out by Close, many corry lake-basins
are only in part rock-basins, they being often
partly formed by a bar of drift across the mouth of
the corry, while some only occupy hollows in an
accumulation of drift. In some of the corrys in
which there are rock-basins, also in others in which
there are none, there is a total absence of drift.
This is remarkable, as from C. King's account of the
dying out of the glaciers on the mountains of the
Pacific slope, it would appear that these, the last
parts of the glacier, are enveloped in accumulations
of moraine drift, and we should naturally expect
that in these cold north and east corrys the ice must
have lasted longest.

In some corrys and cooms the lakes are dammed
in by moraine drift, but in others the drift bar is
evidently of meteoric origin. As far as our experi-
ence goes, every coom or corry is associated with two
or more breaks crossing one another obliquely ; and
if the description of the formation of the cooses on
the Galway coast is referred to, it will appear that
at least one of these break-lines must join into the
old coast-line. This break-line may be perpendi-
cular or oblique to the coast-line ; and if the latter,

COEEYS WITH OE WITHOUT LAKE-BASINS. 139

and there is a sufficient catchment above it, the
hollow formed by the break, especially during wet
weather, will be occupied by a mountain torrent.1
These carry down yearly a greater or less quantity
of detritus, thereby forming a bar across the
mouth of the coom or corry, and impounding the
water behind it, thus forming a lake-basin partly
rock and partly drift. Such bars are always more or
less regular, which distinguishes them from moraine
drift similarly placed, as in general the latter is
more or less irregular, unless its form has been
modified in outline by marine action. Furthermore,
meteoric bars are seldom as compact as moraine-
drift; consequently, it is not unusual to find lake-
basins, so built up, having an overground outlet only
in very wet weather, while at all other times the
surplus water percolates through the meteoric drift
bars.

1 Mackintosh describes such mountain torrent-courses under the
Cumberland name, " Rake."

CHAPTER X.

THE VALLEYS OF SOME OF THE IRISH LAKES.

WE have described the lakes of larconnaught, but if
we turn from that country to South-west Cork or
West Kerry, areas also remarkable for their numerous
lakes, we find very similar relations existing between
the breaks, faults, and lake-basins ; for although
these portions of Ireland are much less faulted than
larconnaught, yet they are traversed by numerous
master-joints and faults, on which the lake-basins are
situated. All the .areas we have mentioned are more
or less mountainous, but the connection between
breaks and lake-basins can also be traced in the low-
lands of Ireland. Lough Neagh,1 the premier lake,
is evidently situated on lines of breaks, the principal
of which bear respectively about N. 10 W., N. 5 E.,
N. 40 E., and N. 55 E., while there are others of
older date bearing more or less obliquely to those
mentioned.

Lough Corrib,2 the second largest sheet of water
in Ireland, has also conspicuous lines of breaks,

1 Admiralty Chart, No. 53, Ireland. 2 Ibid. No. 2318.

THE VALLEYS OF SOME OF THE IRISH LAKES. 141

along which lie the different deeps. In a paper
written some years ago on this lake-basin/ I ignored
the open joints, faults, and the like, and tried to
prove that the excavation of the lake-basin was due
nearly solely to ice action. Since then, however, it
has been found that lines of faults or breaks traverse
it, while every bay or arm in the N.W. part is con-
nected with one of these lines, and each deep lies
along one of them, or at the crossing of two or
more ; but that ice was the great carrier would still
appear correct, as its traces are quite conspicuous
everywhere in and about the basin, while the forms
of the lake coincide with the courses of the different
ice-streams. This lake is partly situated in a car-
boniferous limestone country, and partly in a country
occupied by Silurian and metamorphic rocks ; and as
the latter rocks are much more broken up and faulted
than the former, the most of the part situated in the
limestone, is much shallower than the rest. There
are two places in which there are deep abrupt holes,
that could not have been scooped out by ice, and
probably were formed by water that had a sub-
terranean passage, assisted by a fissure due to a
fault or shrinkage. These deeps will again be men-
tioned when we are describing the Lough Mask basin,
but prior to entering into that subject we should say
a few words on Sluggys, Swallow-holes , Turlougks,

1 Geological Magazine, Nov. ] 866.

142 THE VALLEYS OF SOME OF THE IRISH LAKES.

Pot-holes, Pipes, and the like, as all the low-lying
lakes in Ireland seem to have now, or to have had at
a former period, some connection with them.

We have already pointed out how a portion of
land may sink if an underlying subordinate bed or
portion of a bed is subtracted by water. Sometimes
these subsidences form bowl-shaped hollows, but at
other times a regular hole will form, called a sluggy
or swallow-hole in Ireland, and a pot-hole or pipe in
other places. Sluggys generally are somewhat like
the shape of an hour-glass or of a funnel ; they may,
however, have vertical sides. Pipes and pot-holes in
limestone and chalk countries are supposed by sub-
aerialists to be " produced by the slow dissolving
action of water charged with carbonic acid." This
view seems to be now generally adopted ; but although
in some few cases carbonic acid may act alone, yet
it appears to us to act in most cases in conjunction
with lines of joints, structure or other weaknesses
in the rocks. It is argued that because some small
pipes can be proved to have been excavated by dis-
solving action, that all large pot-holes are similarly
produced ; this, however, seems to be a weak
argument. In various places in Ireland holes
similar to what are called " pipes" in England are
in course of formation among the tracts of carboni-
ferous limestone, and from these we learn that such
holes may be formed by two different processes — one

THE VALLEYS OF SOME OF THE IRISH LAKES. 143

variety being excavated from the top downwards, and
the others mostly from the bottom upwards. The
growth of the first may be studied on the shores of
any lake situated in a limestone country such as
Lough Corrib. Here, when the drift covering has
been recently removed from the rocks by the water
of the lake, beautifully polished, etched, and scratched
surfaces are exposed. Those that now, since the lake
was lowered,1 are exposed only during the summer
months, are full of minute round holes ; those that
were formerly exposed only during the summer months
are full of larger holes ; while those that are exposed
to all weathers are pierced through and through with
circular holes. This circular weathering is peculiar,
as it does not seem to occur except in the vicinity of
lakes. It usually begins on the ice-polished surfaces
by forming lines of minute holes along the strise ;
but if the rock is affected by joints, the holes will
more rapidly increase along the joint lines, so that
in a very short time all appearance of the stride
disappears. Moreover, even if the rock is not jointy,
all appearance of the striee will shortly disappear, as
these scratches run regularly alike over the chemically
hard and soft portions of the rock, while the latter
will weather much more freely than the former.
Professor Melville of Galway seems to be of opinion

1 About twenty years ago, during the works for the Lough Corrib
Navigation, the summer level of the lake was lowered three feet.

144 THE VALLEYS OF SOME OF THE IRISH LAKES.

" that these holes are caused by the acid generated
from the decay of mosses or lichens, humic acid
being formed from the decay of the vegetable
matter that might grow in or be swept into the
small hollows in the stone, and carbonic acid from
the final decay, the latter acid saturating the water,
which would then act on the limestone. Once the
hollow is begun, all acid in the water remaining on
the stones, along with what may form from the decay
of any vegetable matter that may be swept into them,
will be concentrated as the water evaporates ; there-
fore principally act on the bottom of the hollow, and
thereby bore the cylinders through the blocks."

In this way the holes which are like inverted funnels
might also be explained, for as such holes deepened,
the water could not, in them, evaporate as quickly as
when they were shallow ; therefore the contained
acid would act on the sides as well as on the bottom
of the holes, and thereby enlarge as well as deepen
them. If the acid generated from the plants is the
cause for these weatherings, the reason for their being
only found in the vicinity of lakes may be accounted
for by supposing that the moisture from the lakes
helps the growth of the acid-forming vegetables.

Against these suggestions it should be mentioned
that in one locality, Dringeen Oughter, on the shores
of Lough Mask, a cup weathering occurs, not on the
surface of the rocks, but on the surface of one of the

THE VALLEYS OF SOME OF THE IRISH LAKES. 145

beds in the face of a low perpendicular cliff. This
cliff margins a turlough, and the usual winter level
of its water seems to agree with this line of weather-
ing, the note made being, " Cup weathering at the top
of the winter floods, but over it are two feet of rock ;
these holes may be possibly due to the decay of
plants."1

Away from lakes a weathering generally takes place
in connection with the joint-lines. If the rocks are
thin bedded, it breaks them up into a very coarse
shingle, but if thick bedded, the weather will open
narrow lines of more or less deep fissures. Such
fissures, although connected with, are not -the true
pot-holes, as for the latter to be formed there must
be portions of the rock of a softer consistency than
the rest, so that some places in the mass will weather
more freely than the rest, in which places the pot-
holes form. If due solely to the dissolving action of
acid on a homogeneous rock mass, pot-holes ought to
be circular. This, however, is rarely the case, as in
general they are more or less rudely oblong; their
longest axis always coincides with the jointing of the
rocks. Further more, the pot-holes usually occur in
systems of lines ; and our colleague, Mr W. Topley,
F.Gr.S., when writing of the pot-holes in the chalk
bounding the Medway valley, says, " The marked
parallelism of the long pipes at Maidstone is an argu-

1 " Memoirs of the Geol. Survey of Ireland," Ex. sheet 95, p. 47.

K

146 THE VALLEYS OF SOME OF THE IRISH LAKES.

ment in favour of their having been originally started
along joints or' fissures."

A pot-hole formed in a sheet of limestone will have
a deposit of clay at the bottom of it, the insoluble
residue left after the rest of the rock has been carried
away in solution through the cracks and joints of
the rocks, while if the rock contains nodules of chert
their debris will be mixed with the clay. It is the
same with pot-holes under drift, except that not only
the bottoms, but also the sides, will have a clay
lining. This is as might naturally be expected. As the
holes became deeper and wider, the drift coming in
from above would force out the clay and form a coat-
ing round the walls ; or if the holes were filled by a
more recent accumulation of drift, during the sub-
sequent weathering the water percolating down over
the bed of limestone would carry the residue along
with it, and thus form the clay lining. It has been
suggested that the clay in the pot-holes in the chalk
came in from above. This may possibly be the case
in some instances, but in most it is impossible, as
the clay at the bottom of the holes and lining the
sides usually far exceeds in quantity the clay that
would be necessary to form a horizontal sheet over
the top of the hole, if of an equal thickness to the
layer of clay that all round the pot-hole intervenes
between the drift and the subjacent rock. In some
of the subterranean caves brought to light during

THE VALLEYS OF SOME OF THE IRISH LAKES. 147

quarrying or other works, thick deposits of clay
occur, evidently the insoluble residue of the lime-
stone. As this clay is exactly similar to the clay
lining the pot-holes, it seems to suggest that both
were due to the same cause.

The swallow-holes, formed from below, mark the
lines of subterranean streams. In company with
our colleague, the late Mr F. J. Foot, M.A., &c., we
explored many of these passages, they being of
frequent occurrence in the Counties Clare and Gal-
way, and in all places found that they were induced
by joints and other breaks in the strata along
which the water worked, gradually widening them,
partly by dissolving away the rock ; but after the
passage had become large, and the stream had
increased in size from the surface drainage being
diverted, the current acted more like an overground
one, abrading as well as dissolving away the rocks.
In underground rivers and streams during flood,
when the passages are choked with water, the latter
acts upwards in jointed parts and other weak
portions of the roof, till eventually an opening
connected with the surface is formed, in consequence
of a portion of the superincumbent mass giving
way and falling in, while afterwards the holes are
gradually increased in size by meteoric abrasion.
Pot or swallow holes in all stages of progress may
be seen in the plains of Gralway and Mayo ; the rock

148 THE VALLEYS OF SOME OF THE IRISH LAKES.

sometimes being covered by boulder-clay or esker-
drift, at other times by a meteoric accumulation
formed of the insoluble portion of the limestones
that has weathered away. If a swallow-hole forms
in a low place, the river during floods will overflow,
and form a lake locally called a " blind lough " or
turlough. These usually exist in wet weather only,
but totally disappear afterward, leaving in their
place a rich meadow or pasture. Of one of the
turloughs in the County Galway there is a tradi-
tion that it was formed by artificial means, a well
having been sunk that tapped a river and flooded
the hollow, occupying it ever since. In Galway and
Clare extensive areas and lakes are drained through
subterranean rivers, the outlets from some being
unknown.1 This occurs in other places also in
Ireland ; while it appears probable that in ancient
times, when the land was much higher than at
present, some lakes which now have surface outlets
previously had subterranean ones. A description of
one of these river systems, devoid of an open outlet
to the sea, may be given.

Lough Cooter receives the drainage of the N.W.
shoulder of Slieve Aughta. The Beagh river leaves
the north end of Lough Cooter, and flows for about
two miles towards the west, when it disappears in a

1 "Memoirs of the Geological Survey," Exs. and Maps, sheets 115,
116, 124, &c.

THE VALLEYS OF SOME OF THE IRISH LAKES. 149

cavern. From this its course can be traced for
about six furlongs by swallow-holes, called the
Devil's Punch-Bowl, the Blackweir, the Ladle, and
the Churn, to Pollduagh, a cave out of which it
rushes again to daylight. From this, under the
names of the Cunnahowna and Gort river, it runs
by Gort in a northerly direction for about three
miles, when it sinks a second time, about half a
mile S.E. of Kiltartan, at the old castle. From this
it runs under ground for about six furlongs, and
comes to the surface immediately west of the village
of Kiltartan. After sinking and rising two or three
times in Coole demesne, it eventually rises S.E. of
Eaheen House, and from that flows into Coole Lough.

The Owenshree river, which flows by Roxborough,
takes the ground half a mile W.N.W. of Castle
Daly Bornan Catholic Chapel, and rises again at Coy
Lough, about two miles KE. of Kiltartan, where it
joins into the Boleyneendorrish river. This takes
the ground in less than half a mile, but eventually
appears near Eaheen House, and having mingled
with the Gort river, flows into Coole Lough.
From Coole Lough the waters find their way in
subterranean passages by Caherglassaun Lough to
the sea at Kinvarra, where part, at least, finds
egress through the joints of the rocks in the vicinity
of Dungorey Castle.

In Coole demesne a subterranean stream flows

150 THE VALLEYS OF SOME OF THE IRISH LAKES.

southward from Corker House to join the open river.
This must come from the Boleyneendorrisb river, as
when there is a freshet in that river, and none in
the Gort river, the river at Coole becomes quite
muddy; but if there is a flood in the Gort river,
a stream flows from Coole up this subterranean
passage towards Corker House. Where the Gort
river takes the ground, on the S.E. of Kiltartan,
there are the traces of two older channels at higher
levels than that through which the water during
the dry season now finds its exit. The highest level
is now entirely stopped, and a stream flows back
along the old course down to the present river.
The middle level, during floods, is still used, and
the water rushing down into the subterranean
channel below forms a small whirlpool.

A very large turlough is formed in connection
with Coole Lough. During the dry weather the
water on every side flows into this lough ; but when
the floods arise, the subterranean passages are not
large enough to carry off all the water, which
therefore fills the lough and overflows to the south,
where it forms a most extensive turlough in the
neighbourhood of the Newcastle racecourse, which
lies to the KW. of Gort.

On the 12th October 1862, cricket was played on
the racecourse of Newcastle, and there was scarcely
any water in the streams, but the succeeding week

THE VALLEYS OF SOME OF THE IRISH LAKES. 151

was very wet, and on the 21st the whole of the
plain was covered with water, over twenty feet
deep in places. The area under water, including
the flooded land about Coole Lough, was at least
500 acres ; but when we consider the extent of the
water-basin which drains into Coole Lough, it is not
surprising.

Some of the lakes and turloughs on the low
ground are affected by the rise and fall of the tide,
the rising tide damming up the egress of the fresh
water, which accordingly rises in the lakes or tur-
loughs. This cannot be observed during floods, as
from the expanse of water the rise and fall would
only be a few inches, but during dry weather it is
most perceptible. This phenomenon can be very
well seen in the holes in the vicinity of the mine on
the west of Caherglassaun Lough, although six or
seven miles from the sea at Kinvarra.

Lough Mask lies on the north of Lough Corrib,
and is in some respects similarly circumstanced, as
the rocks of the area occupied by its basin are in
part of carboniferous age and partly much older, the
latter being greatly broken up by faults and the like.
The lake-basin1 has a bearing of about 1ST. 20 E., similar
to the general bearing of the main joints in the coun-
try on the east, while to the S.W. are two arms or
bays, branching from the main basin. The greatest

1 Admiralty Chart, No. 2318, Ireland. '

152 THE VALLEYS OF SOME OF THE IRISH LAKES.

deep of the lake lies near the western shore, and has
the same bearing as the lake itself, the main joints,
and also the ice-striae ; from which it would appear
that ice, taking advantage of the joint-lines, was the
main excavator of the basin, more especially as all the
deeps, except in one place, are more or less gradual
and regular in outline, and might have been cut by
an agent going from the S.S.W. toward the N.N.E.
In this deep place there are no data by which a con-
nection between it and the breaks in the country on
the west can be traced ; but we know that the country
to the N.W. of it is very much cut up with faults,
while the rocks are jumped and shifted; one large
fault, a downthrow to the N.E., striking for the
S.W. end of the great deep (over 150 feet), the deep
having a transverse widening in its line of bearing.
The bays forming the S.W. arms of Lough Mask
are each known to occur along a line of fault, while
we learn from the chart that the different shallows
and deeps occur respectively on the up- and down-
throw sides of the faults, the changes from a shallow
to a deep hole being quite sudden. Lough Mask
drains by subterranean passages through the barrier
of limestone that on the south-east divides it from
Lough Corrib, and in the deep just mentioned there
is a hole remarkable for being on nearly the same
level as the deepest hole in Lough Corrib, the former
being 127 feet lower than the Ordnance datum line,

THE VALLEYS OF SOME OF THE IRISH LAKES. 153

and the latter 124 feet, which would seem to suggest
that these holes may have been the connection
between the subterranean passage and the drainage
of the valleys when the land was at a higher level than
at present. When this basin, and also that of Lough
Corrib, were filled with ice, the water associated with
the latter must have found a vent somewhere, and
probably it was through such deep places ; while after
the ice disappeared these may also have acted until the
land sank so low that there was no fall from them, or
until they were silted up by matter carried into them
by rain and rivers. Lakes in a limestone country are
usually very irregular in outline, and at first it might
be supposed that there is no connection between their
shape and the structure of the subjacent rocks. On
an examination, however, it generally appears evident
that the bays and all wide stretches across the lake-
basins conform with lines of breaks or displacements,
while the minor features of the coast-lines are due to
the weathering along joint systems or lines of bed-
ding, generally the former.

The basin of Lough Derg, through which the
Shannon flows, well illustrates the effect of breaks on
a lake-basin. On looking at the chart of this lake,1
it will be seen that by a few displacements the basin
might be made to occupy a N.N.E. and S.S.W.
valley, and that each of these displacements nearly

1 Admiralty Chart, No. 1552, Lough Derg, Ireland.

154 TPIE VALLEYS OF SOME OF THE IRISH LAKES.

coincides with the strike of the direction of the pre-
viously-mentioned faults connected with the groups
of hills called Slieve Bernagh and Slieve Aughta.
From Killaloe to Rinnaman Point, the bearing of
the lake is nearly south and north ; there the direction
changes, although no fault is known to cross the basin.
From Rinnaman the deeps extend for four miles
towards the N.N.E., when they are probably crossed
by a fault, north of which they bear north and south ;
this fault, however, has not been proved, but that it
exists seems probable, on account of the position of
the old red sandstone in the hill KE. of the Cornagoe
valley.

A little farther north the deeps run into the great
east and west reach that extends between Scarriff and
Youghal bays. This east and west stretch lies in
the continuation of the limestone valley which
separates Slieve Bernagh from Slieve Aughta, and
this limestone seems to be brought into its present
position, not only by a synclinal curve, but also by
faults. On the north of the valley a large fault, a
downthrow to the southward, has been proved, while
near the south margin one or two lines of breaks
seem to exist ; but they could not be proved through
the valley on account of a great accumulation of drift
obscuring the geology hereabout. One of them was
proved, however, farther west in the low country in
the line of this valley, and in its strike are all the

THE VALLEYS OF SOME OF THE IRISH LAKES. 155

deeps that occur in the great east and west expanse of
Lough Derg. At this reach the S.S.W. and N.N.E.
lake valley seems to be shifted eastward nearly three
miles * to the entrance of Youghal Bay, from which
the deeps extend N.N.E. to a little south of Illaun-
more, where they are crossed by the north fault of
the Scarriff valley, which changes their bearing to
nearly north and south, while farther N.E. of Goose
Bay, the great deeps (over 70 feet) end where the
basin is crossed by the eastern continuation of the
Cloonnagro and Corra valley fault. In the north-
eastward of Goose Bay, the trough of the basin runs
nearly N.E. and S.W. to off Drominagh Point, near
which it crosses the fault supposed to run nearly
west and east from Lough Atorick ; while farther
north, an east and west reach, extending between
Cloondavaun and Terryglass bays, lies on the eastern
extension of the fault proved at Woodford. Still
farther northward, the original lake-basin extended
in a N.E. direction, and the relations between it and
the other faults in Slieve Aughta could be pointed
out ; but as this part is now silted up, nothing further
need be said about it.

There are also other breaks that appear to come
into the Lough Derg basin from the S.E., as a rude
parallelism exists between the bearings of the

1 Such a shift may appear enormous, but as large a shift has been
proved in the Maum valley, County Galway.

156 THE VALLEYS OF SOME OF THE IRISH LAKES.

different bays. We have not, however, as carefully
examined any of this ground, except the valley of
Youghal Bay, in which a fault evidently exists. This
lake is one of the natural reservoirs on the Shannon,
and at certain seasons the water is very muddy,
while at other times there is a great evaporation from
it, which causes large deposits of mud and marl ;
therefore from the soundings very little can be
learned as to the nature of the original bottom of the
basin, in addition to the two facts of the deeps being
in the lines of the break, or at the junction of two
or more, and of the islands, rocks, and shoals being
on the upthrow sides of the faults. This latter fact is
very apparent, except in the great east and west reach,
on account of the throws of the south faults of the
Scarriff valley being undecided.

We have next to consider how the rock-basin of
Lough Derg was excavated, for although the water
is now, in places, edged with drift or alluvium, yet
formerly the area was nearly, if not quite, surrounded
by rocks. The sea probably was the first excavator,
marking out, along the faults and breaks, valleys and
ravines afterward to be occupied by ice and rivers,
but when it retired, the other denudants did more
or less work. Principal Dawson, LL.D., Mf Gill's
College, Montreal, has pointed out, in relation to
some of the large North American lakes, that
apparently the original surface passages from them

THE VALLEYS OF SOME OF THE LRISH LAKES. 157

have been obliterated, and the water forced to find
other outlets. This may also have been the case
in regard to the basin of Lough Derg, as the valley
extending from the long east and west reach through
Tough al Bay round the hills called Slieve Arra, and
down the valley of the Kilmastulla river to the
valley of the Shannon, a few miles south of Killaloe,
is occupied by an accumulation of deep drift, prin-
cipally gravels and sands, apparently of the " Esker
sea " period. This drift may be of any depth, and
fill a deep valley ; and if such a valley once existed,
meteoric abrasion, or even sea action, would have
been capable of excavating out the basin of Lough
Derg about 60 feet below the present surface
of the waters of the lake, that is, down to a level
nearly equal to the height of the barrier of rocks that
form the rapids and fall of Doonass in the neighbour-
hood of Castleconnel. Such a passage would drain
all the upper part of the lake-basin, except four
small deeps, one northward of Illaunmore, one im-
mediately west of that island, and two to the S.S.W.
of it ; but it would be incapable of draining a long
narrow tract in the S.W. arm of the lake, also a
portion of the east and west reach, they respectively
being over 60 feet in depth, and in many places
over 100 feet ; the deepest place, which is situated in
the latter, and lies a little to the N.B. of Parker's
Point, being 119 feet. Mr John Ball, F.R.S., &c.,

158 THE VALLEYS OF SOME OF THE IRISH LAKES.

in a paper on " Soundings in the Lake of Como,"
has pointed out as to a lake-basin, " Supposing the
rocks on either side to be of equal hardness and
similarly stratified, it is safe to affirm, that if they
had been hollowed out by glacial action or by
aqueous erosion, the slope would be steepest on the
concave side of the bend, in those parts of the lake
where the glacial stream was turned aside from its
previous direction." This Ball has shown is not
the case in the basin of the Lake of Como ; neither
is it the case in the Lough Derg basin, as at all
such bends the slopes are steepest at the convex side
of the bends, while the deepest part of each cross
section is nearest to the same side.

After carefully contouring and examining the
charts of three Irish lakes, Loughs Corrib, Mask,
and Derg, we have found, in all, sudden deep holes
which it seems impossible either the sea, ice, or
meteoric abrasion could have excavated; while as
they occur on or at the junction or crossing of
breaks, we would suggest that they are in part
due to the fissures which were formed by the con-
traction of the rocks, and that subsequently most,
if not all of them, may have been connected with
subterranean passages, which at different periods
drained or helped to drain the lake-basins. If the
Lough Derg basin had been, for ages, occupied by a

1 Geological Magazine, vol. viii. No. 8, August 1871.

THE VALLEYS OF SOME OF THE IRISH LAKES. 159

glacier, most, if not all the loose portions of the
rocks should have been removed out of it, leaving
the ice, prior to its final disappearance, compara-
tively speaking free from rock detritus contained
in it, to encumber the lake-basin. At the present,
the deepest spot in the lake is only eleven feet
below the low-water of ordinary spring tides at
Limerick, the soundings on the chart having been
reduced to the level of 108 feet above that height ;
but as the level of the water of the lake is so much
higher, there would be an underground drainage if
these holes were connected with subterranean
passages. During the glacial period, the water
under the ice would have found vent through these
passages, denuding away their walls, and enlarging
the deeps from which it flowed. After the glacial
period, water may still have flowed through these
holes, until eventually the land sank so low that
they were incapable of acting, or they were choked
by the deposition of mud or marl. But even now
there is reason for supposing that such passages
may be partially open, as in the summer less water
leaves the lake-basin at Killaloe than flows into it
by the main feeder at Portumna and from the
numerous smaller tributaries. Part of this deficit is
certainly due to evaporation, but all of it can not
thus be accounted for.

Many of the Irish lake-basins which now have

160 THE VALLEYS OF SOME OF THE IRISH LAKES.

surface streams flowing from them, especially when
in the carboniferous limestone, may have had an
underground drainage. This is suggested by the
many systems of lakes connected with subterranean
rivers that still exist in different parts of the
island. We have already described those connected
with Coole Lough, near Gort, County Galway, and
we may now give a brief description of the river
Fergus, County Clare, from the pen of the late Mr
F. J. Foot, more especially as the lakes connected
with it are of considerable size.

" The river Fergus rises in Lough Fergus, be-
tween Corrofin and Ennistimon, at an elevation of
about 350 feet above the sea ; flows eastward and
northward for two miles and a half, when it receives
the Clooneen river ; thence it takes an easterly course
for a mile and a half, when, on entering the limestone
ground, it suddenly disappears in a swallow-hole
or vertical cavity in the rock. Half a mile to the
east it again emerges to the light, from a cavern
called * Poulnaboe,' from which it flows down into
Inchiquin Lough, and thence into Lough Atedaun.
No visible river flows out of this lough, but the
Fergus is supposed to have a subterraneous course
in a direction of about E.S.E. to Dromore Lough,
whence it flows southward, now above and now below
ground, to Ennis, and thence to the Shannon."1

1 " Maps and Memoirs, Geological Survey," Sheets 122 and 123.

THE VALLEYS OF SOME OF THE IRISH LAKES. 161

If the deeps in the basin of Lough Derg below
the 50-feet line of soundings were mapped, they
would make a S3rstem of lakes somewhat similar to
those of this part of Clare, provided that each deep
were connected with the next by a subterranean
passage, while the great deep in the east and west
reach had a passage opening somewhere below the
present sea-level.

Before leaving these lakes, we may refer again
to Lough Corrib, as the river flowing from it has
suddenly become dry four times during the his-
torical period, namely, in the years A.D. 1178, 1190,
1647, and 1683. In the paper previously referred
to,1 I suggested that these failures of water might
be accounted for by subterranean passages, as dur-
ing very low tides the water from the lake would
force out the sand, or whatever else choked these up,
while the return of the tide would fill them up again ;
and if such passages do exist, they must be connected
with the former drainage of the basin.

1 Page 141.

CHAPTER XL

GOUGES AND RAVINES.

IN Great Britain and Ireland most of the valleys
are more or less wide, with sloping sides, and have
evidently suffered from various denudants since they
were first formed, having been probably two or
three times submerged and exposed to marine
denudation, and as many times raised up, so as to
come within the influence of the atmospheric agencies
or ice. In tropical climates this does not seem to be
so often the case, as many gorges and ravines are
well developed, and apparently the only denudant
that has acted on them is meteoric abrasion. To
those in Abyssinia we may draw attention, as they
have been lately described by Mr W. J. Blanford.1
This observer has stated that no faults seem to exist
in the ravines, and that they could not possibly have
been excavated by either the sea or ice action ; but as
he does not take into consideration the contraction of
rocks as they come to the surface of the earth, he is
led to believe the valleys were formed solely by
meteoric abrasion. Such a theory would require an

1 "Geology of Abyssinia," pp. 86 and 87, 154 and 155.

GORGES AND RAVINES. 163

enormous length of time for their formation ; while
in one instance, that of Lough Ashangi and its
tributary streams, the author cannot account for the
disappearance of the detritus excavated out of the
tributary valleys. If, however, it is allowed that
rocks, when brought up to the surface of the earth,
contract more or less, and form open fissures — not
necessarily vertical displacements, but only breaks in
the continuity of the beds — such gorges as those in
Abyssinia would be easily accounted for, without
either a long period of time being expended in their
formation, or any large quantity of matter having been
denuded out of them.

In such a narrow valley as the fissure formed by
the contraction of a mass of rocks, denudation from
water would principally take place at the bottom,
deepening it more quickly than it would widen it,
except in a very damp climate, where a protecting
envelope rapidly grows which might prevent the
bottom of the ravine from being denuded ; this may
be due to different circumstances. If trees or other
protecting plants grew on the tops of the cliffs, all
meteoric abrasion would be prevented from working
downwards ; consequently it could only act horizon-
tally, or inward from the sides of the ravine. Or a
hard rock may cap soft ones — soft sandstones in
Abyssinia being under bedded igneous rocks — this
also would prevent denudation from above. Besides,

164 GORGES AND RAVINES.

as previously stated, inland perpendicular cliffs,
especially in friable rocks, are inclined to remain
perpendicular even in our temperate climate, as
the denudants that principally act on them are the
wind and heat; and if wind can act so effectively in
this country, what would it not be able to perform
in those countries where the heat is excessive and
hurricanes common.

It has previously been pointed out that some of
the ravines in larconnaught seem due nearly solely
to the contraction of the rocks, and greater effects
might be expected in a country like Abyssinia,
where the rocks are exposed to a tropical heat ; and
if at the first these deep narrow gorges were thus
opened, rain and rivers would deepen them, while
the nearly perpendicular character of their sides
would be preserved principally by the action of the
wind, denudation from above being prevented by
the luxuriant growth of tropical vegetation, or by
the capping of igneous rocks. Of debris to be
carried away by the streams there ought to be very
little in addition to that abraded off the bottom of
the gorges, as nearly all of what was denuded by the
winds would be borne away upwards to be scattered
over the high lands.

The contraction of the rocks would account not
only for the formation of the ravines, but also for
lake-basins like that of Lake Ashangi, without the

GORGES AND RAVINES. 165

aid of much denudation or any convulsion of Nature.
It has been already shown that when two or more
fissures meet or cross each other, a greater or less
vacancy is formed (fig. 5, PI. I.) ; and from an examina-
tion of the geological map accompanying Blanford's
description, we learn that various valleys radiate from
this lake-basin, and if valleys, probably also breaks.
Here, therefore, a greater or less vacancy ought to
have been formed, and after it had been modified
by meteoric abrasion, it would be represented by the
present lake-basin. Blanford has suggested that
this lake-basin " must be of very small geological
antiquity, or it would have filled up long since." This,
however, would be quite unnecessary if the valleys
and basin are principally due to the shrinkage of
the rock ; as then the materials to be denuded would
be of but small amount, and any that did go down
may be yearly carried away by a subterranean passage
similar to that which Blanford supposes to exist ; l as
other lakes with similar outlets have been found to
be capable of discharging the detritus brought into
them by streams. This is particularly evident, both
in the Counties Clare and Galway ; as many of the
lake-basins, there, would long since have been filled
up by the solid matter borne into them, were it not

1 Mr Blanford points out that circumstances over which he had no
control prevented him giving the time he would have wished to the
examination of the Abyssinian lake-basins, but to this lake-basin he paid
particular attention.

166 GORGES AND RAVINES.

afterwards carried out of them by the water. The
power of water to keep clear a river-bed having an
underground vent, is exemplified in the Beagh River,
County Galway, the stream that flows from the north
end of Lough Cooter. This river, after an open course
of about two miles, becomes subterranean. At and
near its disappearance its bed is enclosed by high banks
of boulder-clay drift, which contain blocks of lime-
stone and sandstone. These banks are yearly more
or less denuded, and the blocks in the drift are nume-
rous ; yet after a flood few of them remain in the bed
of the river, it being for the most part occupied by
a flinty, angular gravel lying on the denuded lime-
stone rock. During low water no open vent seems
to exist through which the blocks could be carried,
the water flowing into a pool with a muddy bottom,
at the base of the cliff. The limestone blocks might
be in part dissolved and carried away in solution :
this, however, could not happen with the sandstone.
But a close examination explains the process. The
vent, as viewed during low water, is a filter of stones,
with a greater or less coat of slime ; when, however,
a flood comes down, the mud and stones are disturbed
and a passage opened, which increases more and more
till a whirlpool is formed by the rush of the water
that rolls the stones over one another, and thus grinds
them up. Some may even find their way into the
subterranean passage; as lower down, where the stream

GORGES AND RAVINES. 167

again comes to daylight, blocks and fragments of
sandstone have been observed.

The previously described lakes of Clare, which have
subterranean outlets, act somewhat similarly ; for if
rain comes on after a drought, they rise at first
rapidly, while subsequently, although more water
may be flowing into them, their surface will be lower,
showing that at the first the passage was stopped by a
deposition of mud or marl, which the rush of water
had first to dislodge, and then carry away, before ob-
taining a free passage for itself to run off.

Similar reasoning may be applied to account for
the present condition of Lake Ashaugi, as all detritus
washed into the lake may be disturbed and carried
away during sudden floods. It may be objected, that
if detritus can be thus carried away through sub-
terranean passages, it is quite unnecessary that the
gorges and lake-basins of Abyssinia should be
supposed to be due to surface shrinkage, as all the
detritus denuded out of them may have been thus
disposed of. But let us not slight the significant
facts that the basin lies at the junction of a number
of valleys; that as "no ice ever existed in the
country,''1 there was no denudant capable of exca-'
vating out the lake-basin ; that as " there is a sub-
terranean passage from the lake," 2 there must be a
fault or break connected with its basin; and that

1 Blanford. 2 Ibid.

168 GORGES AND RAVINES.

prior to the formation of the lake-basin there was no
receptacle for the deposition of the debris denuded
out of the valleys ; even if we quite ignore that one
process would take ages for its accomplishment, while
the other would require a comparatively short space
of time.

In one of the "Memoirs of the Geological Survey
of India," Mr A. B. Wynne, F.G.S., gives a map and
description of Mount Sirban, in the Upper Punjaub.
The hill is thus described : — u It has an elevation of
6243 feet, with an elongated oval base, is entirely
isolated from the surrounding hills by deep narrow
glens, and is penetrated by steep-sided ravines,
radiating from the summit. Its form is massive,
and its outline heavy, presenting convex curves to
the northward, suddenly interrupted by precipices,
which, facing to the southward, extend along its
crest, and send rugged broken spurs into the valley
below." Wynne seems to have been principally
employed in determining the age of the different
rocks entering into the structure of the mountains,
yet he ascertained that the principal " passes or
valleys " coincided with lines of fault, and in his
sketch-sections the relations between the features of
the hills and the lines of breaks are most evident.
Also, Mr J. 0. Ward, F.G.S., an extreme subserialist,
has to allow when describing the scenery of the Lake
District, England, that " lines of faults are often

GORGES AND RAVINES. 169

found to run through its mountains-gaps or
passes."

The gorges that have been mentioned seem princi-
pally due to faults and shrinkage fissures, but there
are others that appear to be nearly solely due to the
weathering out of courses or dykes of rock. Those
due to soft or " rotten " courses of rock often occur
in granite countries, where narrow, deep passes, with
steep or overhanging walls, often cut through a hill
or mountain range. Why these narrow, rotten courses
should occur in granite has not as yet been explained ;
but they weather much more quickly than the mass
of the rock; this being probably due not only to a
different chemical composition, but also to their
being intersected with innumerable small, irregular
shrinkage fissures or cracks, through which frost,
heat, rain, and wind easily penetrate into the rock, dis-
integrating it, and carrying away the particles, there-
by quickly forming more or less deep, narrow ravines.
Small ravines of this class are not uncommon in
our granite-hills, but they are seldom as well
developed or as striking as those of some other
countries. Mr John Muir, when describing the
newly-discovered " living glaciers " in California,
mentions the " narrow-slotted canons, called devil's
lanes, devil's gateway," &c., which are often from
100 to 200 or more feet deep, while they may be only
10 or 15 feet wide. Many of these gorges he finds

17K) GORGES AND RAVINES.

to be filled by glaciers " still engaged in cutting into
the mountains like endless saws."

Some such ravines may possibly be due in part to
shrinkage, as it is not uncommon to find between
the rotten granite and its walls a thick parting of
flucany stuff, or a thin rib, or even a good metal-
liferous vein ; any of which would be due to a shrink-
age fissure. These partings and ribs have been ob-
served along the walls of many of the courses of
" rotten granite " in West Galway, while some of
the metalliferous veins in Cornwall are connected
with courses of " soft growan ; " and from Wyley's
description of the mines in Namaqualand, South
Africa, it would appear that some of those lodes are
similarly circumstanced.

The denuding out of dykes of fault-rock, and
consequent formation of gorges or narrow fissures,
have already been described, and we may now add
that dykes of igneous rocks, when weathered away,
may leave very similar passes. These, indeed, may
have been at first shrinkage fissures, which sub-
sequently were filled with the intrusive rocks ; as it
is not uncommon to find the rock on both sides of
a dyke unbroken or unbent, which could scarcely be
the case if the igneous rocks had forced open the
fissure they now occupy; besides, in some cases ribs,
and even thick mineral veins, occur alongside dykes
of igneous rocks, as if there had been a shrinkage

GORGES AND RAVINES. 171

after the first filling of the fissure, which has caused
a second fissure, now occupied by the minerals. To
return, however, to the gorges now in question — no
matter what was the original cause of the fissures,
the present gorges are due to the weathering away of
igneous dykes, which happen to be in these cases
more easily denuded than the associated rocks. In
the west of Galway and Mayo there are some
marked passes of this kind which for miles have
nearly perfectly level floors ; these are locally called
" Bohernacolley " (The hags' road or path), as they
are supposed to have been formed by witches.
Here the dykes are generally a variety of whinstone
which weathers rapidly, principally by chemical
action, leaving standing on both sides walls of granite
or metamorphic rocks. In other places, however,
there are dykes of felstone, which at first sight might
be expected to resist denudation better than the
associated rocks ; but they do not, on account of in-
numerable systems of joints, which break them up
into a small angular gravel. Here it should also be
mentioned, although not connected with gorges, that
some whinstone dykes in that country, although
to the eye very similar to those that weather away,
have resisted denudation better than the metamorphic
and other associated rocks, and now stand out in
thick wall-like masses, stretching in more or less
regular lines along and over the hills.

CHAPTER XII.

THE KIVER VALLEYS OF SOUTH-WEST IRELAND : THE
VALLEY OF THE WEALD, AND THE FIORD OF
KILLARY HARBOUR.

IN a paper " On the Mode of Formation of some of
the River Valleys in the South of Ireland," * the
late J. Beete Jukes, F.R.S., suggested that subaerial
denudation was the principal carver of the physical
features of the south of Ireland. The reasons on which
this eminent geologist founded this theory may be
epitomised as follows : — 1st, Limestone once existed
over the whole of the S.W. of Ireland. 2d, The
valleys are not connected with faults or fissures. 3d,
Marine denudation only acts with a broad, horizontal
movement, tending to plane down the land to its
own level. 4th, Marine denudation cannot produce
ravines or narrow, winding valleys. 5th, All glens,
ravines, and winding valleys have been excavated by
either ice or rain and rivers ; and 6th, That the in-
ternal forces of disturbance must have ceased to act
long before the present surface was formed.

1 Quarterly Jour, of Geol Society of London, Nov. 1862, p. 379.

THE RIVER VALLEYS OF SOUTH-WEST IRELAND. 173

The first of these propositions Mr Jukes subse-
quently gave up, and had to allow that the opinion of
more than one of his colleagues was probably right,
namely, that the carboniferous slate and Coomhola-
grits of S.W. Cork were the representatives of the
carboniferous limestone of the central plain, and that
the latter rock never existed in that country. This,
however, does not much affect the present subject,
as some of the other rocks are nearly as easily de-
nuded as limestone. Of the other propositions, none
seem to us to be proved. We shall begin with the
second and sixth taken together.

In the river valleys of S.W. Cork we find the
geology concealed by alluvial deposits, the relations
of the rocks on one side of these flats to those on the
other being only conjectural, and on account of the
high dips of the strata, considerable faults might
exist without their being observed ; which seems all
the more probable, from the fact of rocks sometimes
coming down one side of a valley while there are none
on the other side.1 Besides, all the valleys in the
country that extend northward and southward are in

1 In the valley of the Boyne, where the viaduct crosses the river, in
the vicinity of the town of Drogheda, there is no surface appearance of
a fault further than the river valley ; yet when sinking the foundation
for the piers of the bridge, at 20 feet on the Meath side nearly horizontal
calp limestones were found, while for the Louth pier an excavation
over 90 feet deep was sunk without coming to any rock, there being
between the two places a great downthrow to the northward.

174 THE RIVER VALLEYS OF

more or less parallel systems, which includes not only
the valleys, but all associated faults and master-
joints. In the river valleys the connection between
the valleys and faults may not be apparent; but on
an examination of the cliffs, it is found that there is
not one of the fissures extending to the coast-line
which is not connected with a break or fault in
the underlying rocks. Furthermore, in those por-
tions of S.W. Cork where mining operations have
been carried on, slides, heaves, or cross-courses have
been proved under every transverse valley, ravine,
fissure, and river or stream course that has been
mined under ; and such facts suggest that all the
transverse river valleys in S.W. Cork are connected
with lines of breaks or faults. The longitudinal
valleys have still to be considered ; but as no mining
operations have been carried on across them, and as
they are more or less filled with boulder-clay or mo-
raine drift, an examination of them is very unsatis-
factory. Although faults can only be proved to extend
along one of them, yet it is most probable that they
do exist in all. Jukes states that it is probable that
a band of limestone extends up the valley from Kil-
larney to Mallow ; this, however, is far from being
proved, as S.W. of Kanturk the coal-bearing beds of
the coal measures are found close to the Old Eed
Sandstone, while from that westward to Mill Street
there is scarcely room for any limestone to come in

SOUTH-WEST IRELAND. 175

between the coal measures and the Old Eed Sandstone.
Even if there are limestones, it is scarcely possible
to deny that a great fault, with a downthrow to the
northward, exists here, which can be traced from Dingle
Bay on the west, past Mallow towards Mitchelstown,
while a branch (pointed out in chap. vii. p. 101) seems to
run to Dungarvan. In this line of country are situated
the valley of the Glenflesk River and the major part
of the valley of the Blackwater ; consequently neither
of these valleys can be said to be unconnected with
faults. To the south of this line of fault all the rocks
are twisted and folded, sometimes the folds being even
inverted ; while north of it, except in its immediate
vicinity, the rocks usually lie in gentle synclinal and
anticlinal curves. Running across this great east-and-
west fault are others that have a northward-and-south-
ward direction. These in places shift the main east-
and-west valley and the other nearly parallel valleys ;
therefore, it is not unreasonable to suppose that these
cross-faults were formed after the valleys. These, then,
are movements which have more or less affected the
present surface of the ground. Furthermore, when
we know that the surface of the sea has been at least
350 feet higher, relatively, than at present since
the great glacial period, and afterwards has had at
least one or two changes of level, it seems highly
probable that there should have been some relative
movement among the different beds of rocks, more

176 THE RIVER VALLEYS OF

especially as their continuity is broken up by various
systems of master-joints.

Now, to proceed to the third and fourth proposi-
tions— if they are found to be incorrect, it follows that
the fifth must be incorrect also. If the land-level
is stationary, or if it is gradually rising, the natural
tendency of the sea's action would be to form a
plain of denudation ; but if the land-level is sinking,
the result will be different, for although the sea
may tend to form a plain, it will not be one solely
of denudation, as the marine action fills up all the
low places, but does not excavate them. It would
appear that the relative level of Ireland has been
lowered since the historical period, as we know the
time when the sea flowed into Lough Swilly, and
other low places that are now bays ; while we have
traditions that the sea has encroached in other
places, as for instance in Galway Bay, the ancient
name of which is Lough Lurgan. Archaeological
discovery would lead us to believe that such tradi-
tions are correct, as in late years on the Aran
Islands have been found human habitations and
structures, which can be traced under the sands
below low- water mark ; while in various other places
on the coast of Ireland, bogs containing trees and
plants similar to those of the inland counties,
are found at low-water mark of spring-tides, they
being in places buried from twelve to twenty feet

SOUTH-WEST IRELAND. 177

deep. In such places the sea does not form a plain
of denudation, but if given time enough, it may form
one of accumulation. Although the sea action may
have a tendency to plane down all land to its own
level, it cannot act so in all places, even if the
land is stationary or rising. If all the rocks and
different beds are homogeneous, it might so act ; but
on a coast like that of South-west Ireland it must
operate more quickly along soft strata, while the
harder rocks resist its efforts. The irregular outlines
of the coast seem to have been formed in this way ;
long narrow bays being excavated in the places that
were occupied by the softer rocks, while the hard
rocks form headlands, islands, and off-shore rocks
(carrigSj carrigeens, and skelligs). Subserialists
may state that such bays are submerged longitu-
dinal meteoric valleys ; to us, however, it seems that
most of the valleys of S. W. Ireland originated as bays,
which are now more or less completely emergent,
and that the marine action which we see to be at the
present day shaping the lower ends of those valleys,
is but the present continuation of that by which the
upper parts of the valleys were formed.

The transverse valleys also may have been cut
by marine action. At the present moment, in the
south-west of Cork, the sea is excavating out the
fault-rock, and forming narrow guts and ravines
identical in shape with those that cross the inland

178 THE RIVER VALLEYS OF

ridges, and form the transverse river valleys ; as, for
instance, the sea is at present working across the
neck of land that separates Dunmanus and Schull Har-
bours, and across that between the north and south har-
bours on Cape Clear Island. If river action is appealed
to as having formed these parallel transverse ravines,
where did the water come from that cut the passes,
mentioned in a former chapter, through the headland
and mountain ridge south of Ballydonegan Bay? To
get a water-supply, it would be necessary that the
bay should have been once high land ; and if so,
what has become of this ? Eain and rivers could not
have denuded it away, and as " the internal forces
of disturbance had ceased," it could not have sunk.
As from ocular demonstration it would appear that
the sea of the present day is excavating transverse
valleys along breaks in the rocks, and as most
of the transverse valleys in South-west Cork have
been proved to lie along breaks, it seems un-
reasonable to say that marine action, or "the
internal forces of disturbance," could have had
nothing to do with the formation of the tranverse
valleys across the inland ridges.

The sea may act very unequally, as we have
said, along the bedding, cutting long bays into soft
beds ; but when it works perpendicularly, or nearly
so, to the strike of the beds, it may denude more or
less regularly, wearing away bed after bed. On

SOUTH-WEST IRELAND. 179

account, however, of the jointed and faulted condition
of the rocks, it often can advance more rapidly in
certain places than elsewhere ; for if it meets with a
dyke of loose fault-rock, or a tract of strata broken by
joints or faults, it works more quickly along these,
thereby at such places excavating a passage across
the strata, whether hard or soft. After crossing hard
beds, however, besides advancing, it will also work
sideways, eating out longitudinal hollows along the
soft strata. Work of this kind can be studied in
Cork Harbour, the sea having cut narrow north-and-
south guts through two bands of grits of Old Red
Sandstone age, while in the intervening Carboni-
ferous limestones and shales it is excavating E. and
W. bays. It might be argued that none of this work
should be claimed as due to marine denudation, be-
cause that when the land was relatively higher, a river
may have flowed through Cork Harbour, while tribu-
tary streams, with the auxiliary meteoric abrasion, was
excavating out valleys in the limestone and shale,
which now are submerged, and form the lateral bays.
Such may have been the case in other places, but here
we know that the land is relatively sinking, and has
been doing so for centuries, while at the present day
the sea is yearly denuding the coast-line more and
more. Consequently it is only leaving fact to go to
supposition to state that a force which is not now
acting probably did work which we know by ocular

180 THE RIVER VALLEYS OF

demonstration another force is actually performing.
At the present day the sea is denuding away the soft
rock, while, except in broken places, it does little
work on the hard Old Ked sandstones and grits. And
if it is capable of executing this work now, why was
it not able to do similar work in bygone ages ? And
the present work, if subsequently slightly modified
by meteoric abrasion, would be similar to the present
features of the adjoining valleys.

Cork Harbour points out the process by which the
sea is prone to act, besides showing the share that
wind has in marine denudation. There the sea has
worked in along the principal -breaks, which in all
that part of the country bear about N. 20 W. The
sea having breached the softer strata, and having
thereby obtained access to the site of Cork Harbour,
its further operations were influenced by the prevailing
winds ; and as these blow principally from the west
and south-west, the greatest denudation was accom-
plished in the eastern arms of the estuary ; so that
now, although the sea is still carrying on its original
work along the N. 20 W. line of broken rocks, yet
the bay forming the harbour has been excavated
principally to the eastward of that line. Similar cut-
tings across hard strata with associated longitudinal
bays along the intervening soft strata occur in various
other places in that neighbourhood ; however, it is
unnecessary to multiply examples, as the work in all

SOUTH-WEST IRELAND. 181

is similar. If the land were to sink below its
present level, the sea would gradually enter all
the low-seated transverse valleys, as well as the
longitudinal valleys, accomplishing at least some
denudation as it advanced; but if the land were
to rise subsequently, rain and rivers would take
possession of exactly the same valleys and ravines,
and commence to denude ; therefore it seems to be
as much a question of time and opportunity as of
efficiency, which has done most of the work ; since
whichever held the ground longest ought to have
had most effect, other things being equal. Another
thing militates against meteoric abrasion, unaided by
faults, having cut the transverse valleys ; and that
is, that the sides of such valleys are more or less
abrupt, whereas this denudant usually tries to form
slopes. It must, however, be allowed, as shown pre-
viously, that when this force works conjointly with
breaks, abrupt steeps may sometimes result.

It has been shown that the sea is now excavating
longitudinal valleys nearly similar to those that now
exist in South-west Cork, allowing for subsequent
meteoric abrasion and ice action ; also, that it is able to
cut transverse valleys, while the positions of all the
transverse valleys, and probably all the longitudinal
ones, were determined by systems of breaks or faults.
Therefore it seems evident that the present valleys
are not solely due to rain and rivers, but rather to

182 THE RIVER VALLEYS OF

that action combined with glacial and marine denu-
dation, and that all were generally led by the breaks
and faults in the rocks.

S.W. Cork, as also most, if not all of Ireland,
during the "Esker-sea" period, was relatively about
350 feet lower than at present, which is proved by
the raised beaches, terraces, and the like, found in
various places.1 Such a change of level would lay
most of the valleys of this country awash, and place
them in such a position from currents and tidal-
waves, that the sea would have the opportunity of
doing more work than at present. And that the
Esker-sea did a considerable portion of the denuda-
tion seems probable, as the rivers that now occupy
the valleys since the retirement of the sea have not
been able to clear out the great mass of sea-formed
detritus, the result and evidence of marine denuda-
tion, consisting partly of Esker gravel, partly, per-
haps, of estuarine deposits ; even the old terraces and
bars of the Esker-sea remain, in places, nearly intact.

Before, and during part at least of the " Esker-sea "
period, the mountains in South-west Ireland were snow-

1 Since this was in press, our colleague, Mr J. Croll, in one of his
able papers, has shown that as the northern ice-cap advanced or re-
treated, the level of the sea oscillated, while the land probably remained
stationary. This will account for the very uniform altitude of the
ancient sea-beaches ; thus removing a great stumbling-block, for if the
land had been elevated, the movement scarcely could have been equal
everywhere. Ancient beaches now found at exceptional heights, pro-
bably point to real movements in the land's surface due to local dis-
turbances.

SOUTH-WEST JKELAND. 183

clad, while the valleys had their systems of glaciers,1
a large glacier occupying the valley of the Flesk,
while the moraine-drift left by others occurs in various
places. The drift due to the Flesk valley glacier
forms a flat-topped bank, as viewed from the Lake
Hotel, Killarney ; and "this thick mass of drift con-
ceals all the rocks along the base of Mangerton, Cro«
hane, the Paps, and the Caherbarnagh Mountains, a
distance of fully thirty miles." Here, as well as in the
other valleys where glacial-drift has accumulated, rain
and rivers have done very little work in re-excavat-
ing the valleys ; while in all the valleys opening west-
ward marine action is apparent, all the glacial-drift
below the 350 feet contour-line being more or less
denuded and washed into gravel and shingle, the
deposit of round shingle in the country north of
Mangerton and Crohane being quite remarkable. In
the valleys opening southward and eastward the result
of the marine action is not so striking ; still we may
suppose that such action took place there, as sands,
gravels, and shingle are found at the lower levels, and
moraine-drift at the higher.2

" Memoirs of the Geological Survey," Ex. sheet 173, p. 7.
2 In a valley opening south in the neighbourhood of Hungry Hill, on
the north of Bantry Bay, there is unmistakable evidence of a glacier
having come down within 140 feet of the present sea-level since the
" Esker-sea " period. This, however, seems to be an exceptional case,
and may have been similar to one of the glaciers only just discovered
by Mr John Muir in some of the Californian mountain gorges — this

184 THE RIVER VALLEYS OF

When rivers occur in flats bounded by cliffs, the
rivers are supposed to have formed the flats. In some
cases this may be right, but it is by no means neces-
sarily so, as the sea will sometimes do exactly
similar work in an estuary or fiord. The fiord called
Killary Harbour divides the County Mayo from the
County Galway. It is over ten miles long, and
usually less than half a mile wide. The five miles
toward the west bear N. 60 W. ; the four next miles
run nearly west and east, while the eastern part has
a general bearing of about N. 60 E. It is known
from the geology of the adjoining country, that the
gut occupied by the fiord coincides with different
lines of fault, and that each bay and turn in it are
also due to faults, some of these being of immediately
Post-silurian age, others of Post-carboniferous age
but pre-glacial, and some probably post-glacial. It
is also known that previous to its being occupied by
the sea, ice flowed down it. This is proved by
the presence of the moraine-drift that was left on
dressed, grooved, polished, and etched rock-surfaces,
which drift is now being excavated into and carried
away by the sea.1 Since the ice occupied this

glacier having occupied a similar gorge. On the north of these hills the
gravels of the Esker-sea are well developed.

1 It has been said that because a glacier flowed down this valley prior
to the present occupation of it by the sea, the latter could not have
made it. This, however, does not follow, as the sea may have formed
it before the ice invaded the country, when the land was rising out of
the water during a pre-glacial elevation of the country.

SOUTH-WEST IRELAND. 185

valley, the land has been relatively 350 feet lower than
at present. This is proved by gravel terraces, raised
beaches, and shelves cut in the hill-sides, sometimes
rock, sometimes glacial-drift, not only in this valley,
but in the different adjoining ones. In this valley the
altitude of the gravel terraces is about 350 feet,
south of Derrinkee Bridge, about nine miles N.E. of
the eastern termination of the present sea bay. The
accompanying sketch is by our colleague, Mr J.
Nolan. In Glenanane, and north of Tawnyard
Lough, which lie respectively south and north of the
valley, a little above the end of Killary Harbour,
there are shelves or terraces at a height of about 350
feet ; in an arm from the tributary valley of Fin
Lough there is a flat, in Maura valley terraces, while
elsewhere the traces of shelves can be detected at
similar heights. There are, however, other terraces
much better developed and marked than those enu-
merated, which can be traced from Derrinkee to
Glenanane, having a regular fall from 350 feet to
175 feet in a distance of about eight miles. On
account of this slope, it might be said that they
must be river gravel. This, however, appears to
us to be impossible, as during the "Esker-sea"
period, when these gravels must have been formed,
the whole of the central plain of Ireland, and the
valleys in the neighbouring hills, were under the sea
which reduced the present mountain-tops to islands.

186 THE RIVER VALLEYS OF

Consequently there was no land for a river of these
dimensions to come from ; we must therefore look for
some other explanation for the sloping terraces.

We have just mentioned that at no very remote
period the West of Ireland was at a relative lower level
than at present, as traces of the old beaches are found
in different places near the coast of Gal way, Clare,
Limerick, Kerry, and Cork. Since then the land must
have relatively risen higher than it is at present.
Afterward it again sank, as proved by the bogs and
human structures submerged beneath its waters, while
now it appears to be for a time stationary. If we
examine Killary Harbour, we find at its east end a
gravel terrace, and others occur at the mouths of the
principal rivers flowing into it, while most of the rest
of the old sea-margin is marked by shelves cut in the
drift or rocks. If we next examine the chart,1 it ap-
pears that, bordering the sides of the gut occupied by
the bay, are sand and gravel terraces that slope from
the tidal beach in the neighbourhood of Lenaun to
the mouth of the harbour ; while more or less near
the centre there is a hollow which in general slopes
seaward, the only considerable deeps being at the
narrows in the vicinity of Inishbarna; while farther
in are some holes connected with the junction of the
lateral and the transverse faults. If, therefore, the
land was gradually raised, these marginal sloping

1 Admiralty Chart, No. 2706, Ireland, West Coast.

SOUTH-WEST IRELAND. 187

terraces, as shown in section (a, a, fig. 24, PI. IV.),
would be found at the sides of an alluvial flat (#, b)
in which flowed a river (c) ; furthermore, the river
probably would be in a supplementary flat bounded
more or less by sloping gravel cliffs.1 Advocates of sub-
ferial denudation have pointed to similar flats and ter-
races to prove what this agent can do ; as they seem
to believe that only rivers can form sloping terraces.
It has, however, been shown that the sea is capable
of forming them ; and not only them, but the supple-
mentary flats bounded by gravel cliffs, which mark,
not a river flat, but the margin of a gradually-rising
estuary bottom. Even the gravels owe in a great
measure their origin to sea action ; as the detritus
carried down into the estuary by the rivers is a baga-
telle when compared with the quantity of sand and
gravel that was formed by the sea from the washing
and grinding-up of the moraine-drift. And similar
features would be displayed by the elevation of most
estuaries ; namely, a terrace at the head of the valley,
with minor terraces at a similar level in those places
where streams or rivers flowed into the old bays, with a
shelf or cliffs marking the old sea-margin; also, slop-
ing terraces from the terminal terrace to the mouth

1 If the land were to rise 200 feet, the terraces at Inishbarna would
be about 130 feet above the water, while those at the end of the bay
would be nearly 200, giving a fall of the slopes of about 70 feet in nine
miles, about equal to the fall of the terraces in the upper part of the
valley.

188 THE RIVER VALLEYS OF

of the bay, with a river flowing in a valley, often
more or less flat, between the sloping terraces. While
the sloping terraces may be quite conspicuous, the
marginal shelves may be more or less obscure, as
they must be subsequently modified, or even obliterated
in places, by meteoric abrasion. When first these
sloping terraces were observed in the valleys of lar-
connaught opening to the west, we were inclined
to consider that the land had sunk more on the west
than on the east ; but afterwards, when such terraces
were found in valleys opening eastward, we were
forced to look for another explanation; and the theory
we now put forward is founded on the facts recorded
in the charts of different estuaries and bays, not only
in Ireland, but also in Scotland.

The work done in Killary Harbour and Erriff
Valley since the ice left them may be thus sum-
marised. As the land sank, at the beginning of the
ie Esker-sea " period, the sea was clearing out part of
the boulder-clay from the valley, and in places doing
a little rock denudation. Part of the gravels and
other detritus was carried out to sea, but a consider-
able portion was left behind to fill up hollows, and
form a gently undulating bottom to the bay, and
sloping flats in the bays and broads. Subsequently,
as the land rose, the sea partly cleared out the
gravels it had previously redistributed, but left
terraces as monuments of its former activity. In

SOUTH-WEST IRELAND. 189

the present bay the sea has been so long at work,
that nearly all the old gravels have disappeared,
and it is now clearing out what still remains of the
boulder-clay, besides doing some rock denudation.
Meteoric abrasion has not as yet been mentioned ;
it must, however, have materially aided the sea,
both during its advance and retreat, as it is still
doing at the present day.

Here we may digress and point out the nature of
estuarine deposits, and of the fossils and pebbles
found in them. In some estuaries the gravels and
sands will be sharp and clean, like those on an open
seaboard ; but in most estuaries they are more or
less dirty, clayey, or peaty, from their vicinity to the
land, and the inability of the sea, confined as it is,
to wash them properly ; or storms may bank up the
water during floods, and cause all the dirt brought
down by the rivers to be deposited inside. In Wex-
ford Harbour, on the south-east of Ireland, during
gales from the south-east, the water has sometimes
been four feet higher than ordinary spring-tides.
Some estuary deposits have been mistaken for
glacial-drift, while in reality they are only the
washing and rearrangement of such kinds of drifts.
In many places on the coast of Ireland the sea is
bounded by high glacial-drift cliffs which are yearly
more or less denuded. In summer weather shelly
sands and muds may be deposited close up to these

190 THE BIVER VALLEYS OF

cliffs ; while during the winter these shelly deposits
are covered over by a drift, more or less clayey,
containing numerous ice-dressed blocks and frag-
ments. These glacialoid drifts have led to innumer-
able mistakes ; as they have been supposed, as in the
Counties Dublin and Wexford, to be a newer glacial-
drift overlying a shelly gravelly drift ; while in fact
these are both members of the same drift, formed
under different circumstances, and in places graduat-
ing into one another.

If a valley were excavated solely by rain and
rivers, the gravels could only contain blocks and
fragments of the subjacent rocks, or of rocks
situated higher up the valley, pieces of which might
be carried down to any lower level. Sea-formed
gravel, on the other hand, may contain fragments
from both higher and lower levels, which are either
carried down or driven up by the waves and marine
currents; but the detritus from the upper rocks of
the valley ought to preponderate, as they would
always be coming down in rivers, or by rolling from
heights.

Estuary gravels may, in some places, contain only
fragments and pebbles of rocks from a higher level,
as a stream flowing -into the estuary may supply all
the materials of which such gravels are formed.
From this it is evident that river and estuary gravel
may be nearly similar, as rivers may supply the

PLATE IV.

SECTION.

PLAN.

SOUTH-WEST IRELAND. 191

materials for the latter ; or, on the other hand, as
estuarine deposits may contain pieces of the upper
and lower rocks, and as the river gravels may be
formed from them, the latter gravels may thus
contain innumerable different kinds of rocks.

Estuary muds, and some sands, often contain
marine shells, while gravels and peaty deposits
seldom do. Terrestrial and fresh-water shells may
also occur, especially in the gravels formed at the
margins of the estuary. Thus, in Killary Harbour, in
the accumulations at Leenaun, and at the mouths of
the Bundorragha and Derrynasliggaun streams, there
are more fresh-water and terrestrial than marine
shells, while the bones of land animals are not un-
common ; all being carried down by freshets in the
rivers, and deposited in the estuary. The estuary
of the Shannon, in the neighbourhood of Limerick,
formerly extended much farther than at present,
it having been margined by mud-flats, corcasses,
swamps, and salt-marshes, which are now reclaimed,
some within the last few years. These evidently
were estuary deposits, formed very recently ; as
before they were embanked they were covered during
every spring-tide. In some places marine shells are
very common ; but associated with them are the
horns and bones, and sometimes even entire skeletons,
of the elk, reindeer, red deer, <fec. Some of these
bones were evidently carried down into their present

192 THE RIVER VALLEYS OF

position by the waters of the Shannon, while others
probably are the remains of animals swamped while
feeding on or crossing the marshes, in the same
way as horses or cattle may be swamped at the
present day. Land and fresh-water shells ought
necessarily to occur more frequently in the sands
near the mouth of a river than elsewhere ; but they
may also be carried out to the terrace gravels.
Professor Hennessy, F.E.S., &c., has pointed out
the conditions under which sand and portions of
shells will float.1 On a warm and dry day, the dried
shells and sand, when the tide rises to them, repel
the water, and swim thereon, and as the tide
moves gently past, they rise one by one, and float off.
We have seen shells floating also, after the manner of
boats ; but the sea must be perfectly calm, as the
moment they meet a ripple or breeze, they are over-
balanced, fill, and sink. In this way land shells,
although so frail, may be carried out and deposited
in salt water.

The sea in an estuary is quite capable of levelling
alluvium, even although coarse shingle, and thereby
forming extensive flats ; this, however, is not the
case with a river, as the materials carried by it,
especially if coarse, are usually piled in banks. A
river-bed may be prolonged forward, by the stream
carrying gravel, &c., into a lake, forming a level

1 "Floatation of Sand," Geological Magazine, vol. viii. p. 316.

SOUTH-WEST IRELAND. 193

(srah or haugfi), and eventually a plain bounded by
cliffs ; but in this case neither the flat nor the cliffs
are due to the river action, but to wind combined
with the water of the lake. True, river-flats may be
formed by rivers gradually gating into a hill on one
side, while the debris on the other side is levelled
during floods ; such flats, however, are of small
extent, and in Ireland all the extensive river-flats are
differently formed. When the rivers flow more or
less near the centre of their flats, they add yearly to
the alluvium, quantities of silt and such like sub-
stances that are suspended in the water during floods,
but never gravel and sand ; except immediately below
rapids, where the coarse materials can be driven on to
and scattered over the plain. Irish rivers, therefore,
may be related to the flats through which they flow in
four different ways : — 1st, They may in some places
form their own flats and the marginal cliffs ; 2d, They
may fill a lake-basin with gravel, and form a flat, but
not the marginal cliffs ; 3d, They may occupy old
valleys and raise their floors by annual deposits of silt ;
and 4th, They may flow through old estuary-flats,
to which the marginal cliffs were formed previously.
In the first case, rivers would take ages to form a
flat of any extent, and to lower their beds subse-
quently as the land rose ; during which operation they
would probably leave behind upper-river gravels in
the valleys. In the second case, rivers might possibly

N

194 THE RIVER VALLEYS OF SOUTH-WEST IRELAND.

form upper gravels; for as the land rose and the
embouchures of the lake-basins wore down, the rivers
would partly re-excavate the gravels they had pre-
viously deposited in the lake-basins. In the third
case, the flats may or may not be solely due to the
rivers. When sections are opened across them, it is
often found that at the first they were a bog or
morass, and that vegetable growth and decay formed
the beginning of the flat, while subsequently river
silt was deposited over the peat. In other cases will
be found a substratum of gravel or shingle, probably
an estuary formation, on which the river alluvium
has been deposited. Such rivers, however, might
easily lower their beds if the land rose, and the bar-
rier across the lower end was capable of being easily
denuded. But in the fourth case, rivers have little or
no work to do ; for prior to and during the rising of
the land from under the sea, the flats and terraces,
with the upper and lower gravels, would &e formed.

CHAPTER XIII.

THE RIVER VALLEYS OF SOUTH-WEST IRELAND : THE
VALLEY OF THE WEALD, AND THE FIORD OF

KILLARY HARBOUR — continued.

FROM the description in the last chapter of Killary
Harbour, and the different kinds of estuary deposits,
it is evident there are no proofs that the flats in the
County Cork below the 350 feet contour-line were
formed by the rivers flowing in them, while it
appears highly probable they may be old estuary
bottoms, as the gravels associated with them are at
certain elevations in all the different valleys, as if
due to one universal agent, such as the sea. In some
of these flats the work of rivers is apparent; these
having cut passages here and there, and afterwards
filled up the channels, or perhaps left them as irre-
gular trenches after they had taken new courses.

From S.W. Cork we now proceed to the valley
of the Weald, which has been put forward as one
of the great proofs of enormous subeerial denuda-
tion. We will specially refer to Messrs Foster and

196 THE RIVER VALLEYS OF

Topley's paper on it, as these observers have care-
fully examined the geology of the country.1

The Weald is bounded on the north, west, and
south by chalk-hills or Downs, while near its central
line is an axis of hills, which in places is higher
than the average height of the Downs. These central
hills are of rocks the oldest in the area ; consequently
they are hills of elevation, which, however, have been
greatly modified by denudation. If on the rocks
forming these hills the absent strata were replaced,
the hills would be between 2500 and 3000 feet in
altitude^ or in round numbers, about 2000 feet higher
than at present. The North Downs are, on an aver-
age, 700 feet high, and the South Downs 800 feet ;
consequently the central hills would be 1300 and
1200 feet higher than the present North and South
Downs respectively. These are about 18 and 12
miles from the central axis, and there are dips north-
ward and southward (ignoring all minor flexures and
rolls) of about 78 feet and 100 feet to a mile, equal
respectively to about 1 in 68, and 1 in 53, or about
an angle of one degree both ways.

If subgerial agencies are as powerful as some
suppose, it is quite unnecessary to call in any
aid from marine denudation, and it may be supposed

1 " On the Superficial Deposits of the Valley of the Medway, with
Kemarka on the Denudation of the Weald," Quarterly Journal of the
Geological Society of London, November 1865, p. 443.

SOUTH-WEST IRELAND. 197

that this agency has removed at least 2000 feet in
thickness of strata over all the area now occupied by
the Hastings beds, a less thickness over the Weald
clay area, and still less, in different degrees, over the
country now occupied by the greensand and gault.
Not very long since, the Hastings beds and Weald
clay areas was a forest, the growth of which must
have prevented all surface denudation ; and during
this Forest age the rainfall must have been a great
deal more than it is now.1 Although the Hastings
beds and Weald clay areas were protected by their
envelopes of trees, the surrounding chalk downs
must have suffered considerably, which seems proved
by " the beds of unstratified flint-gravel that are met
with in majiy places on the lower greensand, gault,
and lower slopes of the chalk."2 Now, however,
although the rainfall has decreased as the forests are
gone, atmospheric denudation is acting more or less
over the whole area, being accelerated in many
places by the tillage of the land.

The extreme advocates of subaerial denudation may
fairly be asked: — 1st, Why did the forest grow, and
stop the denudation of the Hastings beds and the
Weald clay ? 2d, Why are there not accumulations
of chalk flints on the Hastings beds and the Weald
clay areas, as well as on the gault and greensand ?

1 See page 113. 2 Foster and Topley, p. 446.

198 THE RIVER VALLEYS OF

And 3d, How the subserial agencies at the first formed
an escarpment in the chalk ?

To consider the last first : subaerial agencies, un-
aided, seem incapable of cutting a ravine in homogene-
ous chalk or limestone. We do not know whether a
bare sheet of chalk exists, but many such of limestone
do, and in all cases meteoric abrasion denudes the
whole surface ; so that no ravine, and consequently
no escarpment can form, except the rock is faulted,
jointed, or traversed by some kind of shrinkage fis-
sures, which are acted on by the weather. But as in
such rocks master-joints and faults are nearly always
connected with an underground drainage,1 they can
seldom be the forerunners of valleys that are denuded
solely by meteoric abrasion. Once a ravine or valley
is begun, whether it be due to the shrinkage of the
rocks, an anticlinal curve, marine denudation, or the
scooping out of ice, meteoric abrasion would be cap-
able of materially assisting in developing it; more
especially if the beds dip away from the valley, and
some are softer than the rest, as the basset of the
soft beds will be denuded more quickly, and cause a
hollow in which water will collect, and form a stream
at the base of a cliff; the water conveying off the
debris as fast as it falls. If, however, the beds dip
into the valley, the water will run away from the
cliffs, and all debris that falls will remain at their

1 Whitaker, " Memoirs of the Geol. Survey," Sheet 7, England, p. 96.

SOUTH-WEST IRELAND. 199

bases, till eventually slopes are formed ; on this ac-
count valleys usually move away from their faults, the
rocks on the down-throw side, which usually rise to
the fault, being more easily denuded than those on
the other side. Wind, however, as previously pointed
out (page 80), may act very similarly to a stream of
water in keeping a cliff perpendicular. Joints or
other shrinkage fissures will also affect the weather-
ing of a cliff, according as they are nearly parallel
or perpendicular to the line of cliff, as previously
illustrated when speaking of the marl cliffs in south-
east Ireland (page 51).

In the Weald there would appear to have been
at one time more or less continuous cliffs to the
north, east, and south of the clay country, probably at
the commencement of the Forest period ; these, how-
ever, seem to have been denuded back since then, and
modified by meteoric abrasion, which first changed
the cliffs into slopes, and afterward gradually denuded
the latter backwards ; so that now the escarpments
may be far removed from the original sites of the
cliffs, and during all this time the transverse valleys
across the Downs must have been somewhat simi-
larly acted on. If the sea had formed cliffs to the
Weald valley, it would necessarily have worn back
both the chalk and the harder underlying strata ;
such, however, would not be the case with meteoric
abrasion, as this agent would have greater effect

200 THE RIVER VALLEYS OF

on the chalk, forming a continuous escarpment of
that rock, but leaving behind it prominent masses
of greensand, to mark, but in places only, the site of
the ancient sea-cliff. From this it is apparent, that
although the escarpment is now being gradually
worked back by meteoric abrasion, yet it may have
been due originally to sea-work. The accompanying
sketch maps (figs. 25, 26, PL IV.) will explain how
this may happen. Fig. 25 represents a marine cliff in
one place cut entirely in chalk, and in another part
formed of chalk and greensand ; while fig. 26 repre-
sents the present chalk and greensand escarpments,
part of the latter being the base of the old sea-cliff,
while the sea-cliff that was entirely chalk has been
totally denuded away. If the Weald valley was solely
due to subserial denudation, there ought to be de-
posits of chalk flints over the whole area, and not
only on the newer beds. If, however, the sea formed
the original valley, it would have been capable of
carrying the flints out of it, and consequently flints
would only be found on the beds exposed by meteoric
abrasion, since the sea ceased to act. Furthermore,
when the sea retreated, the forest grew, and occupied
the "Weald clay and Hastings beds areas, protecting
them ; but meteoric abrasion was still working on the
chalk, denuding it backwards, and exposing the green-
sands and gault.

It must be allowed that, at one time, there was

SOUTH-WEST IRELAND. 201

a horizontal mass of chalk over all the Weald, and
that consequently the North and South Downs sank,
or the Hastings beds were shoved up. It has already
been shown, that when a sheet of rock is bent into
anticlinal and synclinal curves, it may form unbroken
arches, or the strata may gape in places, and form
open fissures along lines of weakness, the gaps being
equal to the radii minus the cosines of the angles
of the slopes. This, in the case of the Weald, if we
ignore the minor flexures, and consider it one anticlinal,
would be 18 miles multiplied by 1 minus the cosine of
1° + 12 miles multiplied by 1 minus the cosine of 1°,
which would give a valley only 25 feet wide from
escarpment to escarpment, if the beds opened to-
gether, which, however, is improbable, the different
groups of rocks being made up of such dissimilar
materials. In such a case, each bed would have re-
tained its relative position to its fellows ; but if the
beds were capable of bending without breaking, and
would not stretch, the original position of each would
have to change, as each bed must move on the one
below it up towards the axis of each anticlinal curve.
If, however, the upper beds were ruptured, while the
lower beds were not, it is not unreasonable to suppose,
especially if there was an upward as well as a hori-
zontal thrust, that the upper beds might remain
fixed at their unbroken ends, while the lower beds
would be pushed along below them, and up into the

202 THE RIVER VALLEYS OF

break, such a movement naturally taking place along
a soft, .weak bed. Thus, if the chalk in the Weald was
broken, but fixed at one side, the greensand would
be pushed out from under it along the gault ; and the
Hastings beds might be pushed out from under all,
along one of the Weald clays. Such a movement in
the Weald, although the average angle of dip be only
one degree,1 would form terraces between the outcrops
of the chalk and greensand, and the greensand and
the Hastings beds in the north and south parts of
the valley respectively, 15 feet and 10 feet wide.

As soon as this movement was complete, or even
while it was yet in progress, denudation would be
at work — marine denudation if the movement was
submarine, meteoric abrasion if it was subeerial. Thus
either denudant, if it had time enough, might possibly
have accomplished the work that has since been done ;
but it appears much more natural to suppose that
neither of these agents did all the work, but that
their efforts were combined; each accomplishing its
allotted portion. Le Conte has shown that it is pro-
bable that all elevations and crumbling up of the
earth's crust commence beneath the sea, and all
rocks thus raised must necessarily be exposed to the
full force of the sea prior to being raised above its
influences. In the case of the Weald, the sea would

1 The average angle is higher ; this is the lowest mean angle of dip
that can well be assigned.

SOUTH-WEST IRELAND. 203

at the first remove all broken portions from the
central axis ; afterwards, as the land gradually rose,
it would denude back the chalk, and also form trans-
verse valleys along the different secondary breaks.
The land may even have had various upheavals and
lowerings, at one time being above, and another time
below the sea, and during all such movements it
would be exposed to denudation by the different forces,
and this appears probable from this, that most of
the rivers now flow through the transverse valleys;
but during the different risings and lowerings, such
places would be liable to be deepened by the sea, more
than the longitudinal valleys; which is the reason why,
when the land finally rose, they would form the chan-
nels most likely to be occupied by the rivers. Such
an estuary would also account for the marked escarp-
ment bounding the valley on the north, west, and
south, while none exists bounding the high land in
the centre, for the sea would form cliffs in the chalk
as the beds dipped away from it, but as the beds in
the central axis dipped towards it, .the sea could only
form slopes, it being unable to work back the base of
the escarpment as fast as' meteoric abrasion was wear-
ing away the upper portion.

It has been intimated that breaks do not exist in
connection with the transverse valleys of the Weald ;
but it would appear to us that a fault must occur in
the valley occupied by the Eiver Ouse ; while between

204 THE RIVER VALLEYS OF

Lewis and Brighton, we traced numerous breaks, not
only forming features on the escarpment, but also
across the Downs, to which are due the irregularities
in the boundary of the chalk. Furthermore, Messrs
Foster and Topley's suggestion would corroborate
the idea that these ravines and hollows are connected
with breaks, although these breaks are not marked
on the map ; for they state, " These valleys are pro-
bably due to the dissolving away of the chalk along
lines of underground drainage." Mr Whitaker also
has suggested the same, in relation to the ravines in
the chalk of other places. There are also the ponds
on the Downs, which must be connected with subter-
ranean streams (similar to the turloughs in the lime-
stone districts of Ireland), and become filled during
wet weather (the underground passages being too
small to carry off all the water), but are dry at other
times.

The authors of this paper on the "Weald seem to
believe that in landlocked bays sea action is neces-
sarily feeble. This, however, does not appear to be
borne out by observed facts, as after the high tides
of 1870 we found on the west coast of Ireland, that
on the open seaboard little work was done even on
such frail materials as those forming the sand-dunes,
while in the bays and other landlocked places, cliffs,
piers, embankment roads, and everything the tides
could reach, were more or less injured or carried

SOUTH-WEST IRELAND. 205

away. On an open seaboard the sea can do little
work, unless it is assisted by wind, but in narrow
places the rush in and out must accomplish more or
less work every tide.

It seems remarkable that the gravels of the Weald,
if fluviatile, should all be below the 350 contour-line,
like the gravels of the " Esker-sea " period in Ireland,
and the sea-gravels in North America.1

The gravels of the Weald are said to be fluviatile ;
no positive proof for this suggestion has, however,
been given ; and we have shown that many so-called
river-flats and river gravels are probably the ancient
bottoms of estuaries and the gravels of estuaries ;
as in an estuary sloping terraces of gravel become
formed, while terrestrial and fresh-water fossils may
not be uncommon; for estuary deposits are more likely
than river accumulations to have the bones of land
animals in them, as may be studied in any river during
floods, because all animals drowned are swept down
by the current, and their bodies deposited in the still
water of a lake or an estuary. If there are rivers
flowing into an estuary while the waters of the estuary
are denuding rocks, the gravels found in the estuary
will be composed of fragments of higher beds brought
down by the rivers ; while the local fragments will be
brought elsewhere according to the set of the tidal
and other currents ; and such gravels could not be

3 Principal Dawson.

206 THE RIVER VALLEYS OF

regarded as purely fluviatile. The coarse and fine
deposits in the drift of the Weald valley would appear
to be estuary accumulations, as similar series are found
in all estuaries — in one place nothing but clays and
the like, and in others gravel or shingle ; while rivers
must form alternations of fine or coarse accumula-
tions, according to the height of the waters.

Proofs are not wanting of the valley of the Weald
having oscillated up and down during the most re-
cent ages. According to Mr Drew,1 a bare pole was
put down 70 feet in Romney Marsh without reach-
ing the bottom of the recent accumulations, the
lowest 50 feet of which were sand containing " recent
marine shells, especially cockles." Over this sand there
are in places five or six feet of peat, containing the
roots, stems, and fruit of trees, such as the oak, alder,
hazel, &c., and over the latter a clayey, peaty, or
sandy alluvium. Clay also sometimes occurs over-
lying the peat, while "the whole of the alluvium is
below the level of high water at spring- tides."

According to Dr Mantell,2 " in Pevensey Level
the trunks of large trees have often been observed
imbedded in a mass of decayed vegetables. The sub-
stratum is an inferior peat, with an intermixture of
sand reposing upon a thick bed of blue alluvial clay,
containing marine shells ; " while at Irfield, " nearly

1 "Memoirs of the Geological Survey, England," Sheet 4.

2 MantelTs " South-east of England."

SOUTH-WEST IRELAND. 207

twenty feet " of peat, containing tree remains, was
sunk through, and in various places off the coast
submarine forests are known to exist. According to
this authority, the general section of the low levels is
as follows : —

4. Vegetable mould.

3. Peat with trees, . . . 3 to 5 ft.

C Dark-blue silt (clayey), with ^

2. < fresh-water shells above and > 5 to 25 „
(. marine shells below, . . j

1. Pipe clay, . . . 1 to 4 „

34 ft.

From the above facts it is evident that the land
once stood much higher than at present, during which
time a bay over 70 feet deep was excavated in the
place now occupied by Komney Marsh; that after-
wards the land began to rise higher, and the bay was
filled with estuary deposits. At the first the sea had
free egress into the estuary ; but afterwards it became
a fresh-water lagoon, and eventually dry land, on
which a forest grew and flourished. But subsequently
the land again began to sink and be subject to floods,
while mosses and the other peat-forming plants
established themselves. The trees then began to
decay away, till eventually all were destroyed and
covered with peat. After that the land sank so low
that even the peat could not grow, the place being con-

208 THE RIVER VALLEYS OF SOUTH-WEST IRELAND.

tinually flooded with water, and during this time the
clays, alluvium, &c., were deposited over the peat.
Because a bog containing trees, &c., may be found
inside and outside a sea-beach, it has been argued
that the trees may have grown at their present level,
while since then the sea has moved its beach in land-
wards, exposing the bog and trees to seaward. The
fallacy of this reasoning is easily exposed if we only
examine into the conditions under which the trees
found would grow ; as oak and most other trees can-
not be grown except on drained land, which could
never exist naturally in places below high-water
mark.

CHAPTER XIV.

THE LOCH LOMOND AND OTHER SCOTCH VALLEYS.

SCOTLAND, similarly to Ireland, is intersected by
systems of breaks, but they are in general more
intricate and less regular; this resulting apparently
from their being so numerous and of so many
different ages, the newer deflecting and displac-
ing the older. However, in some localities in
Ireland, such as N.W. Ulster, W. Connaught, and
S.E. Leinster, faults and breaks are just as numerous
and complicated. In the Highlands of Scotland, as
far as we visited them, we did not meet with a valley,
ravine, or lake-basin unconnected with a break. It
would also appear that in most cases there is probably
a connection between ice action and the lake-basins ;
but this denudant seems to have been always led by
the faults, breaks, and other shrinkage fissures in
the rocks. If it is admitted that lake rock-basins
are partly due to ice action, and partly to the con-
traction and the displacement of the rocks, all objec-
tions now raised against the ice theory would be done
away with ; as the hollows at the outset would be
formed by the crossing or junction of breaks, while
subsequently ice action would lift up and carry away

o

210 THE LOCH LOMOND AND OTHER VALLEYS.

all the loose blocks and fragments, thereby clearing
out the basins.

Loch Lomond occupies a remarkable valley, which
has a general bearing of north and south, correspond-
ing with the lie of other important breaks in that
part of Scotland. Extending from this valley east-
ward and westward are transverse features — some
forming valleys, while others constitute greater or
less depressions in the hills. That all these valleys
and depressions are connected with dislocations in
the underlying strata is manifest by the strike of
the rocks being deflected, or the beds of rock rising
to the up-throw of the faults, or by the shifting of
conspicuous beds of rock.

CLoch Lomond must, at no very remote period, have
been a fiord connected with the valley of the Clyde.
This is proved by the raised beaches of the latter
valley being on a similar elevation with the terraces
in the Loch Lomond valley, and the gravel-bar across
the latter, a little to the north of the lake. The lake-
basin, therefore, at that time, was a submerged valley,
which prior to its submergence, if the theory of the
subaerialists be correct, was excavated by rain and
rivers, or ice.

The lake is divided into two portions by the chain
of islands stretching westward from Balmaha. From,
the chart * we learn that south of these islands it is

1 Admiralty Chart, Scotland, Loch Lomond.

, THE LOCH LOMOND AND OTHER VALLEYS. 211

shallow, rarely exceeding 12 fathoms in depth; how-
ever, in a few places it is 13, and in one spot, east
of Inchmurrin, a hole 14 fathoms deep is recorded.
North of the islands the lake gradually deepens to
Boss Point ; it then shallows for a short distance,
being only four or six fathoms deep on Hunter's
Bank, which lies a little north-east of the inver of
Douglas Water ; but on the north of this bank it
immediately deepens to over 25 fathoms, and north-
ward it gradually gets deeper and deeper, till it
attains the maximum depth of 105 fathoms due
west of the hamlet of Culness. North of this place a
deep portion (over 100 fathoms) extends for nearly a
mile; after which the basin gradually shallows to
Whitepoint, between which and the end of the lake
there is another deep portion, about 34 fathoms.

From an examination of the country in the neigh-
bourhood of the south part of the lake, we learn that
there are features connected with breaks running
about N. 30 E., while the deeps in the adjoining
portion of the lake-basin have similar bearings. Im-
mediately north of the islands the direction of the
deeps is not so regular, they in part running N. 30 E.,
and in part nearly N. and S. ; but in the rest of the
lake the deeps extend nearly N. and S. It may be
observed, that although the general bearing of the
lake is N. and S., yet the deep portions in the north
part have not an exactly similar lie; as in places

212 THE LOCH LOMOND AND OTHER VALLEYS.

they incline more or less to either side, from being
deflected at the junctions of the transverse valleys
with the main one. All the deepest spots coincide
with one or other of these junctions.

The shallows in the lake may possibly be due, in
part, to accumulations made when the lake was a fiord ;
similar shallows, however, are not found in the fiord
of the Clyde, and it is probable that since the lake
became fresh water they have been considerably aug-
mented by debris carried on to them by the rivers
.and streams, especially the bank in the vicinity of
the Douglas Water, which has all the character of a
delta, shelving suddenly at its margins, especially
northward.

As already stated, the features of the adjoining
country and the shapes of the bottom of the lake-
basin have a connection between them. The irre-
gular deep, east of Ben Dhubh, occurs where the
nearly N. and S. breaks and the N. 30 E. breaks
meet or cross one another. The sudden deepening
north of Hunter's Bank seems due in part to a fault
with a down-throw to the north, coming into the main
valley from the east. The shallow to the south of
the deepest spot is evidently on the N.W. side of the
fault-line which is associated with the Tarbet valley.
This appears to be a very recent fault, and it has con-
siderably shifted the main fault of the valley. The
Inversnaid and Inveruglass faults also slightly shift

THE LOCH LOMOND AND OTHER VALLEYS. 213

the main fault ; while the deepest spot in the basin
(105 fathoms) seems to be at the junction of the main
and Culness valley faults. We have now stated the
principal facts in connection with this lake-basin, and
proceed to offer suggestions as to its formation.

If this valley were solely due to rain and rivers, it
would necessarily deepen gradually from its upper to
its lower or south end ; this, however, is not the case.^
If due to the erosion of ice, the deeps and shallows
ought to graduate one into the other, and have a
trend conformable with the lie of the valley, and
consequently with the course of the glacier; this,
however, is contrary to facts. Again, marine action
could not possibly have excavated this valley ; on the
contrary, it would tend to fill it up; but the extreme
shallowness of the lower or south portion seems not
to be due to such a cause, as the soundings record a
rock bottom in many places. It should, however,
be pointed out, that in some of 'the neighbouring
fiords, such as Loch Fyne, there are extraordinary <
deeps in the upper portions, which apparently are not
being filled up by sea action.

It has been shown that the valleys and depressions
at the surface are connected with breaks in the strata,
while the bearings of all the deeps in the lake-basin
are similar to those of the features in the adjoining
country, or they have a relation to the several junc-
tions of the transverse valleys with the valley of Loch

214 THE LOCH LOMOND AND OTHER VALLEYS.

Lomond; consequently, we have a right to assume
that the form of the lake-basin is more or less con-
nected with the breaks in the underlying strata. Let
us suppose a great north-and-south break to have
been first formed, with transverse breaks and their
accompanying fissures branching from it. Meteoric
abrasion, or if under the influence of the sea, marine
action, would widen and deepen the fissures or other
vacancies that were thus formed ; or if the climate
became arctic or alpine, ice would catch up and carry
away all loose blocks, forming valleys along the fis-
sures and lines of breaks ; while in the broken ground
at the crossing or junction of one or more of these lines,
the ice would wedge up and bring into the transport-
ing power of the glacier all loosened blocks and frag-
ments of the rocks, and consequently excavate the
rock to a great extent, thus forming the deeps ; then
subsequently produced breaks or dislocations would
shift the work previously accomplished, and more or
less modify it.

By operations such as those mentioned it seems
possible to account for all the phenomena of the basin
of Loch Lomond; ice having accomplished the major
portion of the excavation along broken lines of rock
due to faults and other shrinkage fissures. For the
formation of the deep spot due west of the village of
Culness a second theory may be propounded ; for
when the land was relatively higher, and the deeper

THE LOCH LOMOND AND OTHER VALLEYS. 215

portions of what is now the lake-bed were above the
level of the sea, underground vents may possibly have
existed, as we know they do in other parts of the world.
Suppose the country about Loch Lomond to be 600
feet higher than at present, and rain and rivers to
be excavating the basin. This hole being at the
junction of the main and Culness valley breaks, it
is possible that in this place there might have been
a subterranean outlet, which was capable of draining
the water out of the greater portion of the basin of
Loch Lomond. Such subterranean outlets at the
junction of two or more breaks are not uncommon
among similar rocks in the hills of larconnaught,
Ireland, where the " fault-rock " is of an incoherent
nature or open structure; or when an internal fissure
has not been filled with minerals. Such a theory as
this would necessitate that all the rock debris taken
out of the valley — which may have been more or less
in accordance with the size of the original fissures
due to the shrinkage of the rocks — was carried away
through the subterranean passages ; now we have
previously shown, when describing the subterranean
drainage in the neighbourhood of Gort, County Gal-
way,1 that a considerable amount of detritus, and
even blocks of stones, may be carried away through
such passages. This theory, however, does not appear
satisfactory; for although in most lake-basins, especi-

1 " Memoirs of the Geological Survey, Ireland," Ex. sheets 115, 116. :

216 THE LOCH LOMOND AND OTHEK VALLEYS.

ally at high levels, it is probable there is or was a
certain amount of subterranean drainage from them,
yet it seems scarcely likely that it could have accom-
plished much of the excavation of the basins. We
are therefore inclined to believe, that after the main
lines of the valley were laid out by faults or other
shrinkage fissures in the underlying strata, marine
action, meteoric abrasion, and ice, separately or
conjointly, excavated the basin, that during this
process other shifts occurred which modified its
original form, while subsequent shifts or shrinkings
helped to form the remarkable deep holes. It may
also be suggested that among the later movements
of the surface, the lower portions of the lake may have
been lifted higher than the northern part ; or the
upper portion may have been depressed more than
the south part. That some of the dislocations in
connection with this valley are post-glacial, we are
strongly inclined to believe. Our examination, how-
ever, was too brief and restricted to justify us in
coming to a positive conclusion on this point; but
the features of the country about the north part of
Loch Lomond, and also in the neighbourhood of Loch
Katrine, seemed to indicate very recent movements
and breaks in the underlying rocks.

Before leaving this lake-basin it should be pointed
out, that if at the time it was a fiord there was an
arctic climate, as the fossils found in the raised beaches

THE LOCH LOMOND AND OTHER VALLEYS. 217

of the Clyde valley would indicate ; the fiord may have
been covered with ice, or have had an " ice-foot," on
which was caught most of the debris brought down
from the hills to be floated out to sea (little or none
of it remaining to be deposited in the lake-basin to
silt up the deeps), and if the ice remained longer in
the upper portion than in the lower, the former would
have been more excavated. These suggestions would
apply to the neighbouring fiords also, and to some of
the bays in the north of Ireland.

Our colleague, Mr H. Leonard, M.R.I.A., thus
writes of some of the Scotch valleys : — u In the
Highlands of Scotland I was greatly struck with
the form of the ground \ the resemblance to that of
portions of Connemara being complete. The rocks
are similar in composition, and the physical fea-
tures could hardly fail to command attention, while
the absence of timber increases the opportunities for
observation. The faults here, as in the west of Ire-
land, run principally through the cols or maums, that
of Glencroe passing through the maum at ' Rest and
be thankful.' The historic valley of Glencoe lies
along a line of break in its schistose rocks, which is
very prominently marked from about the centre to
the top of the glen, where the main fault appears to
split into a number, and these are in many cases cut
across by other faults. The glen of the Blackwater
Lochs is another example of a valley along a break.

218 THE LOCH LOMOND AND OTHER VALLEYS.

In this wild and rocky gorge the strata are well ex-
posed, so that the data are easily observed. The bear-
ing almost coincides with that of Loch Leven, in
which the waters of the glen flows. The Caledonian
Canal, which consists of a series of connected lakes,
is also in the line of a great fault, and very many
cross-faults were noted along its route.

" Loch Awe, from the nature of the rock, does not
as plainly tell its tale ; but the facts observed in the
vicinity of Portsonachan, and along its western side,
rather incline to the assumption that it is connected
with shrinkage breaks ; the joints having nearly the
same general bearing, and indicating that two sets of
master-joints aided in producing the physical features
here developed. Breaks or master-joints appear to
run into the two glens at the head of the loch.

" In the Grampian Mountains the resemblance to
Connemara is, if possible, more striking, as the
country is very much faulted, like our own ; and I
cannot help thinking that any observer visiting the
district, supplied with the key obtained from a length-
ened examination of a similar region, may more truly
unlock their history, and, perhaps, cease to be i fully
persuaded that these valleys are to be looked upon as
the results, not of subterranean movements, but of
subserial denudation.' I may mention, that when
travelling through Savoie, Valais, and the Bernese
Oberland, I was greatly impressed with the numerous

THE LOCH LOMOND AND OTHER VALLEYS. 219

examples presented of valleys excavated in the line
of faults. The Arve, Rhone, Visp, and their many
secondary valleys, show countless instances where
subterranean movements have aided denudation in
carving out the features now existing, and in the
narrow rocky gorge where the Aletsch glacier (the
longest in Europe) ends, the work of denudation,
combined with shrinkage lines, is most apparent.
That both agents should be allotted their respective
tasks appears to me necessary in unravelling the
geology of most districts."

An examination of the Chart of Loch Fyne l is not
without interest. The south portion of this fiord, as
far north as Loch Gilp, bears nearly N. and S., but
the rest of it has a general bearing of N.E. and S.W.;
the fiord widening out considerably where these two
portions join into one another. When, however, it
is examined in detail, other peculiarities will be
observed. At the entrance of the bay, and south of
a line (N. 70 E.) drawn through East Loch Tarbert,
the deeps run about N. 15 W.; but at this line they
are shifted considerably towards the west, while north
of it they bear nearly N. and S. to High Rock, which
lies due N.E. of Maol Dubh Point. A little S.E. of
Maol Dubh Point there is a space over 80 fathoms
deep, with one portion over 90 fathoms, and from
this deep there extend others of less magnitude

1 Admiralty Charts, Scotland, West Coast, Loch Fyne.

220 THE LOCH LOMOND AND OTHER VALLEYS.

towards N. 20 W. into Loch Gilp, and N. 15 E. to the
Otters Spit Narrows, the 90-fathom hole being at the
junction of these two lines. Immediately north of
the Otters Spit Narrows the line of deeps is shifted
considerably from the west towards the east ; while
north of this line the deeps bear N. 20 E. till they
meet the break (N. 20 W.) coming down Gair Loch,
at the junction with which there is a deep hole, over
30 fathoms deep, the surrounding bottom being less
in depth. Also starting from this point is another
line of deeps which bears N. 40 E., and extends to
the Minard Narrows. At the Minard Narrows there
is a complication, there being various small islands,
and only one narrow channel, which reaches 20
fathoms in depth. North of these islands the line
of deeps is slightly shifted towards the west, and
it bears about N. 30 E. as far north-east as
Furnace, when its bearing changes to N. 70 E. ;
but in a short time, when Strachur Bay is nearly
reached, it changes to N. 25 E., and this line of
deeps extends past Inverary into Loch Shira. From
a little east of Furnace to Inverary the fiord is very
deep, most of it being over 50 fathoms, while there
are long holes in it over 70 fathoms deep. From
Inverary toward the N. 60 E. the deeps extend for
some miles, while the channel of the fiord at the
north-east extremity bears nearly due N.E.

From the summary just given it is evident that

THE LOCH LOMOND AND OTHER VALLEYS. 221

the fiord of Loch Fyne consists of a series of fea-
tures which are more or less systematic; for the
deep portions extend along regular lines, and where
these lines cross or join into one another, there
are extra deep soundings, and each shift in these
lines corresponds with lines of features in the
adjoining country. G-lenshira is connected with a
break in the strata, and Glenary appears as if it
followed a similar line. However, the drift greatly
obscures the evidence in the latter case ; but the
sudden deep opposite Inverary lies at the junction of
these two lines with those of the breaks that exist
higher up and lower down in the main channel of the
fiord; while a little farther S.W. one of the deepest
spots in the upper portion of the loch is where the
break occupied by the Douglas Water joins into and
slightly deflects the main break. The island and
shoals at Minard Narrows seem to be brought up by
a fault ; so also does the Otters Spit, and the various
islands and shoals in the bay ; but as the country in
the vicinity of Loch Fyne was not all examined, nothing
further can be said about them.

The lower portion of this fiord has a nearly
gradual slope from the Frith of Clyde to the Otters
Spit Narrows, but N.N.E. of these to Minard Narrows
there are deeps, which, however, are not as considerable
as those previously mentioned in the reach between
Minard and Loch Shira. These different soundings

222 THE LOCH LOMOND AND OTHER VALLEYS.

may be accounted for as follows : the lowest portion
is gradually filling up by sea-brought detritus ; the
centre portion is also slightly silting up ; while the
sea has very little power in the upper portion.
Furthermore, ice may have existed longer in the
upper than in the middle portion, in consequence of
which, the former would be more .worn and hol-
lowed out thereby, than the latter, while most of the
detritus brought down would have been caught on,
and carried away by, the ice, so that little or none
of it could now remain in the upper part of the basin
of the fiord.

APPENDIX.

FORMATION AND GROWTH OF SOIL OR SURFACE-MATTER.

WHEN land is first exposed above water, or from
under ice, it is devoid of soil. Soil or vegetable
mould may be earthy, sandy, or organic; it takes
years to form, but it increases much more rapidly
under some circumstances than others; the process
being due to the combined effects of meteoric action,
the growth and decay of vegetable matter, and the
operations of certain animals.

All rocks, no matter how hard and tenacious,
will, in time, weather and disintegrate if exposed to
meteoric action; but the detritus formed may not
always remain to produce soil, for if the land slopes
sufficiently, all, as fast as formed, may be removed
by rain or wind, the latter force being even capable
of removing detritus from a flat surface, especially if
in exposed situations. Many rocks, such as doleryte,
dioryte, granyte, some limestones, &c., are physically
hard, while they are chemically soft ; others, such as
slates, schists, clays, &c., are physically soft, while
they are very little susceptible of chemical deconi-

224 FOKMATION AND GROWTH OF

position ; therefore on rocks of the first class, soil
will form much more rapidly than on those of the
second. Some rocks, however, may weather easily
into a meteoric accumulation, and yet, on account of
a want of a necessary combination of substances, will
be incapable of forming a productive soil. Some
granytes and sandstones thus weather into " cold
soils ; " but if the former be associated with limy
matter, and the latter with marly or clayey stuff, a
u warm " or productive soil is the result. Other
rocks are so chemically formed, that as they
weather nearly the whole of their constituents will
be carried off in solution. Thus in some parts of the
County Galway, over the . carboniferous limestone all
the limy matter has been carried away through
swallow holes or "sluggys," leaving a siliceous sur-
face accumulation, due to the decomposition of the
contained chert. In some low-lying places this
sandy drift may have been carried down from the
adjoining high land ; but when we find it occupying
high land, it must have been formed where we find
it.1 Many earthy limestones weather into valuable
soils. This, however, depends very much on the
nature of the climate ; for while in a moist, cool
country the land over limestone may be most fertile,
in a dry, hot country the land on an exactly similar
rock may be unproductive.

" Memoirs of the Geol. Survey, Ireland," Ex. sheet, 107, p. 34.

SOIL OK SURFACE-MATTER. 225

Boulder-clay drift has in general been formed out
of the denudation of various rocks ; and we find fertile
soils more often over it than in places where the
surface is due to the disintegration of only one kind
of rock. There are, however, exceptions to this rule ;
as some rocks, especially if belonging to the Kaino-
zoic epoch, may be so constituted that they form
excellent soils. Drift, moreover, may be formed
almost solely of one substance, such as clay or sand,
when it will weather very slowly ; or it may contain
subordinate layers or beds of an impervious character,
such as layers of bog iron-ore, or beds saturated
with other minerals, which will retard, or even pre-
vent, the growth of soil in places, or even over large
tracts. In many of the estuaries of South-east
Ireland a sandy marl has been deposited, which, if
exposed to atmospheric influences, would freely
weather into a rich soil ; this, however, in most
places is covered by a ferriferous clayey or sandy
deposit, that will not weather freely or support
vegetation. The good marl was evidently deposited
while the water was deep, all the iron brought
down in solution by the streams from the adjoining
country being carried out to sea ; but when the
estuaries began to fill up, and the muds to be ex-
posed twice daily, more or less of the water evapo-
rated, depositing the iron it contained. In the north
mud-lands of Wexford estuary there is a rich blue

p

226 FORMATION AND GROWTH OF

marl full of shells, under from 18 to 30 inches of a
ferriferous clayey accumulation. The former, when
turned up to the surface during the drainage opera-
tions, was found to be most productive; while the
latter would not grow any crops until it was well
limed. Some of the iron in this accumulation was
probably due to the decomposition of the blackish,
ferriferous limestone of the neighbourhood, but a
great deal of it evidently came down in the waters
of the Slaney and its tributaries from the Silurian
and Metamorphic rock and Granite country on the
west and north-west.1

When a surface is exposed to meteoric influences,
it dries and cracks ; chemical action is also at work,
the latter being augmented by the frequent changes
from wet to dry. At first the growth of soil goes
on very slowly, as wind or rain may carry away a
large portion of the disintegrated matter ; once, how-
ever, vegetation begins, it gets on more rapidly, the
atmospheric influences being enabled to work more
readily in depth along the holes, crevices, and the
like, due to the roots of the plants and the animals

1 In general, bet ween the blue marl and the ferruginous, clayey stuff
there is a greater or less stratum nearly altogether composed of shells,
as if life had suddenly been destroyed. If this has been the case, it
points to a sudden partial upheaval of the land, or, as appears to me
more probable, a ponding up of the water by a change in the position
of the banks and shoals, the ponded-up water evaporating more or less
every low tide, and the iron from it destroying life. Or fresh water
may have been ponded in, which would have the same result .

SOIL OR SURFACE-MATTER. 227

associated with them. It would appear, however,
that in these countries where soil has formed and a
protecting envelope of grass or the like has grown
on it, the increase downward is imperceptible, if any
at all takes place ; the increase that takes place being
upward from the vegetable growth, always assisted
by the work of worms, ants, and other earth-boring
animals. "We are aware that this opinion is con-
troverted, as Darwin seems to be of opinion that the
formation of soil is solely due to worm- work ; l but
after careful examination and consideration, we are
forced to come to conclusions different from those of
that eminent observer. A foreign substance placed
on grassland will be gradually covered up by a growth
of soil over it. This soil Darwin seems to believe to
be entirely due to the labour of earthworms, which
excavate in the ground under the foreign substances
and deposit over it ; so that the total thickness of the
soil is not increased upwards by mould formed from
vegetable decay; but all is taken from below the
foreign substance and placed above it ; thereby adding
to the thickness of the upper stratum of the mould,
and diminishing the thickness of the portion below
the foreign substance. To earthworms cannot be
due the formation of all the soil, for this reason —
all worm-formed mould must be ejected by them ;

1 "Transactions of the Geological Society of London," 2d Series, vol.
v. p. 505.

228 FORMATION AND GROWTH OF

consequently, if the mould was solely due to them,
there would be between it and the subsoil a layer of
coarse sand or gravel, formed from the large particles
they could not swallow. Even from Darwin's ex-
amples it would appear evident that the growth of
soil cannot be due to worms alone ; for spread a
layer of lime on a field, and the worm, to quote that
author, f; is unable to swallow coarse particles, and
the finer earth lying beneath would be removed by a
slow process to the surface." Thus, eventually, all
the matter that could be reduced small enough to be
swallowed by the worms would be brought above the
lime, and only the pebbles and fragments of stones
left below ; so that above there ought to be only this
fine earth, while below there ought to be only gravel
and sand. This is the result that ought to occur if to
the worms alone is due the vegetable soil ; but if they
worked in conjunction with the decay of the vege-
tables, and principally in the soil due to that decay,
there would be a continual shifting of a soil in which
few pebbles ever existed. This, however, would involve
the surface of the subsoil remaining permanent.

Nearly all the examples put forward by Darwin
were observed in rich, highly-cultivated ground,
where earthworms abound ; therefore the growth of
the worm-formed soil must have been more rapid
than would ordinarily be the case, and the part
added, through the decay of the vegetable matter,

SOIL OR SURFACE-MATTER. 229

may not have been very apparent. Nevertheless,
he seems to prove that, in one instance, the vegetable
decay, not the earthworms, buried the foreign sub-
stances, namely, that of the boggy field which was
covered over with a coat of gravel, and in two years
and a half afterwards there was a peaty layer three-
fourths of an inch thick grown over it. Very similar
instances occur, and may be examined in many places
in Ireland among the reclaimed cutaway bogs, or as
they are locally called, Moors. These moors are
generally tilled for a few years previous to being
laid down in grass, after which a coat of marl or
gravel is spread on them. If they are to be kept
in good heart, more gravel or marl must be applied
to them from time to time, and the drainage
attended to ; but if they are neglected, as is too
often the case, they will tend to return to their
former state, and in a short time a layer of peaty
soil will grow on the marl or gravel. It is not
uncommon in these moors, if a section is opened
through them, to see one, two, or even three of
these layers of foreign matter, pointing out the
number of times the moor was " brought in," and
afterwards allowed to run wild.

Any one acquainted with bogs well knows that
earthworms cannot live in them ; a few may be found
in reclaimed moors in the made soil, both while they
are in tillage and under grass ; but once the original

230 FORMATION AND GROWTH OF

boggy nature again predominates, they disappear, so
that they cannot assist in making the upper stratum
of soil above the gravel ; moreover, if this upper
stratum is examined, it will be found to be of the
same platy or rudely laminated structure, as that
of all bogs that grow from the successive layers of
decayed vegetable matter.

Those conversant with highly-cultivated, rich grass-
land, can scarcely have failed to remark the enormous
worm-work that yearly goes on ; but this is not the
case in all lands, for in many (not all) over chalk
and limestone there is little or no worm-work ; so
also in poor sandy soils, or in " slob-land " newly
reclaimed from the sea. On many chalk and lime-
stone lands " stones grow," or in other words, the
surface of some grass-land gradually becomes covered
with stones ; but in poor sandy soils, or in slob-land,
although it may be the work of time, yet eventually
there will be a surface-soil formed by the decay of
the vegetable matter, and all the stones will be
covered up by the growth of the soil. In such soils,
at the beginning of the growth of the vegetable
clothing, earthworms will be rare — in fact, they
cannot live without organic food; therefore until
the vegetable life begins they cannot exist. As
the vegetable soil increases, so will the earthworms,
showing that the two agents work together, also
that the growth of the soil is due, not only to

SOIL OR SURFACE-MATTER. 231

vegetable decay, but also to the worm-work. When
the soil becomes rich, the earthworms do a greater
amount of work, but while it remains poor they can
do little or none, owing to the paucity of their num-
ber ; so that to vegetable decay is principally due
the growth of the first mould.

Lands with a permanent turf or sod, that has
remained untilled for ages, may be used either as
pasture or as meadow land. If the surface-soil
were due only to the earthworms, then in a field all
of which has the same fertility, subsoil, &c., if a part
is used as permanent pasture, while from the rest
hay is always cut, the condition of the whole ought
to be uniform, and over all there would be a gradual
increase of the mould. This, however, is well known
to the farmer not to be the case ; for the mould will
increase on the pasture-land, but not on the per-
manent meadow, unless the latter is cut early enough
to allow of a second growth or " after-grass," which
is left to rot on the ground. And in corroboration
of this principle, all farmers state that machine-
mowing is more severe on meadow-land than hand-
mowing, because the latter does not or cannot cut
as close as the former ; for similar reasons horses
are harder on grass-land than either sheep or cows.
To counteract the injurious effect of removing from
the meadow-land all the vegetation which would
naturally decay on it, the land has to be topdressed

232 FORMATION AND GROWTH OF

with foreign substances. It may be said that on
pasture-land the vegetable products are not allowed
to decay. This is partly true; but if such pro-
ducts are eaten off by the cattle, they are returned
again to the surface ; their fertilising quality being
increased from their having been used as animal
food.

In a comparison between meadows and pasture-
land the difference between sole worm-work and the
conjoint effects of vegetation decay and of the earth-
worms appears evident. Examine a meadow-field
after the hay is cut, and the worm-casts are found to
be few and far between ; but if the after-grass is
allowed to rot on the land, the worms will be more
numerous, working among the decayed vegetable mat-
ter. In pasture-land there will be a hundred worms
for every one in a meadow; the greater number being
found under and associated with the decayed vege-
table matter in the droppings from the cattle.

In some soils, such as alluvial loam, earthworms
will burrow to a great depth ; but they seem usually
incapable of penetrating into the ordinary subsoils
that occur in Ireland. The gravelly subsoils formed
by the esker-drift ought to be soft enough for them
to work into, yet they are never found in it. The
usual subsoil, boulder-clay drift, they never burrow
into, and a not uncommon subsoil in some places,
namely, a stratum of bog iron-ore, they could not

SOIL OR SURFACE-MATTER. 233

possibly enter; yet over all those different kinds
of subsoil the surface-mould increases if the land is
laid down in permanent grass. The beginning of the
formation of the soil over a subsoil of bog iron-ore
cannot be due to anything but chemical action and
vegetable decay, as no worm-work could have been
done there ; and if in such an instance a surface-soil
can be formed without the aid of worms, why should
not similar work go on in other places ? In such
places the formation of soil would be carried on
under most adverse circumstances ; for a bare sur-
face of limonite is a very unfavourable place for
vegetation, and usually it appears due to the decay
of the water lodged on the surface, with perhaps a
slight disintegration of the underlying mineral, from
which are generated lichens and mosses, and event-
ually a peaty soil. It is added to, however, very
gradually ; for in dry weather, there being no depth
of earth, the vegetation withers away.

Land that has been tilled to one depth for many
years will have a surface to its subsoil like a road; and
this is so well known, that to counteract it subsoiling
has been introduced. If such land is laid down in grass,
and subsequently again broken up, the surface of the
subsoil caused by the former tilling will be found in-
tact; but the depth of the mould will have increased in
proportion to the number of years it has remained under
grass. This increase cannot have taken place below,

234 , FORMATION AND GROWTH OP

as the old subsoil surface still remains ; therefore the
mould must have increased in thickness upwards, and
necessarily by the decay of the vegetable substances.
It may be said that this is an exceptional case ; for
this road-like surface would not be formed naturally
over the subsoil. However, if the thickness of the
mould increases downward, as suggested by Darwin,
is it not remarkable that over each different kind of
subsoil the thickness of the vegetable mould should
be so uniform? Naturally the mould is only a few
inches thick over gravel, a little thicker over clay, a
good depth over a subsoil formed of a combination of
clay and sand, more especially if it is limey, while
over an alluvial subsoil it may be deeper still ; unless,
indeed, that meteoric abrasion in each several case
has removed from the surface an exact equivalent
to the increase ; but this is highly improbable.

Mr John Edward Lee, F.S.A., F.GLS., the transla-
tor of Dr Keller's " Lake Dwellings of Switzerland,"
in a note on the depth of soil covering the " Main-
land Settlement of Ebersberg," records a remarkable
growth of soil at Caerleon, South "Wales. Mr Lee
thus writes : — " In a field which forms the south-west
portion of the ancient city of Isca Silurum, I have
frequently excavated for the sake of archaeology, and
in one instance, when the summer was dry, the grass
showed where walls were probably to be found, indi-
cating the ancient Roman houses forming the corner

SOIL OR SURFACE-MATTER. 235

of the inhabited portion, an open space of the street
being between them and the city walls. It was,
however, very singular that these indications, though
correct, were not verified till the ground had been
excavated to a depth of five or six feet ; and before
the actual base of the wall and the floor of the street
were reached, a tall labourer was entirely hidden from
view. The first foot or two may be accounted for by
the rubbish when the place was destroyed, but as no
soil is likely here to have been brought down by floods,
we are almost obliged to attribute the remaining
four or five feet to the annual addition of vegetable
mould. The excavation above referred to is not the only
fact which indicates a great accumulation of soil ; a
handsome tesselated pavement lately discovered in
the churchyard was four or five feet below the present
surface," &c., &c.T This is a startling fact in favour
of the growth of soil by vegetable decay; and Mr
Lee further states, in a subsequent communication
on the subject : " The old town of Isca is on a tongue
of land slightly above the flats on the rivers' banks
(the Usk and the Avon Llwydd), and from the situa-
tion there is no chance whatever of any earth being
brought down from the hills to the place I mentioned."
Although the growth is so large in the aggregate, yet
the yearly amount when calculated seems moderate
enough. It must be about 1700 years since the

1 Keller's "Lake Dwellings," p. 367.

236 FORMATION AND GROWTH OF

Romans occupied the site, and if two feet are allowed
for the depth of the debris of the building, there will
be four feet to be formed by the growth of the soil :
this is equal to 2 '82 inches in a century, or "028 inch
annual growth, scarcely equal to the thickness of five
sheets of foolscap paper, — or, to put it differently,
one inch growth in every 35*4 years. Further-
more, all may not be due to the vegetable decay ; for
as the field is near Caerleon, it is probable that it
has often been " topdressed," a process which would
quickly add to the depth of the soil. It may be
here mentioned, that some years since, a field in
the north part of the County Tipperary was broken
up that had a soil fourteen inches deep, and this field
was known by a man seventy years old to be exactly
110 years in grass. As the average depth of soil in
that part of the county is from ten to twelve inches,
it would leave about 2 *5 inches of soil to grow in the
century; which is very similar to the results obtained
near Caerleon.

Some soils are ready made when they are deposited
on the surface ; as, for instance, the particles carried
down by flood and deposited on callows, corcasses,
and other alluvial flats. Another instance is wind-
borne soil, clouds of fine particles being carried
during dry windy weather from high to low land,
especially if the former is in tillage. Even grass-land
may supply such materials as we have remarked

SOIL OK SURFACE-MATTER. 237

in such places as Devonshire, where after dry
weather clouds of dust are often raised off the pas-
tures. Wynne, in his description of the geology of
Kutch, India, when describing the alluvium, proves
the soil-producing powers of wind. In the early
part of the memoir he mentions the extreme
denudation the rocks suffer from the winds, and
writing of the alluvium, he states : — " The deposits
frequently resemble those of rivers ; but there are
no large rivers in Kutch, and the small intermittent
streams which it possesses would have to wander
laterally to a great extent in order to cover the
country with such detritus. They only appear to
have changed their courses in a few localities near
the coast, and their valleys, though small, are
generally single and separate, from the hills to the
sea."

Some of the Kutch alluvial deposits are salt,
sometimes two or three feet in thickness, due to
the evaporation of floods of saline water ; others are
so impregnated with salt (Kara and Kuller) as to be
incapable of producing vegetation ; while on others
(Laana) there is a scanty growth of plants.

Other soil-formers that are rarely thought of are
the ants. These workers, although such pigmies in this
country, and therefore, compared with the earthworms,
less capable, individually, of work, are so numerous
and energetic, that in the special places to which

238 FORMATION AND GROWTH OF

they resort their yearly work is much more conspi-
cuous than the annual worm-work. In Leicester-
shire, for instance, and elsewhere in central En^-

/ ' O

land, the hill-building ants are a nuisance to the
grazier. In the spring the ants may be observed
beginning their work, and from that time they
carry on their operations all through the summer,
to the late autumn or early winter. On a moor
they raise hillocks scattered about over the ground,-
getting closer and closer together as the colonies
increase. But where the ants are most useful is in
places where crags and large stones are mixed up
with patches of sandy peat. In such a locality they
will always build on a rock, the foundation of their
habitation being at its junction with the soil. These
ants seldom raise their structures as high as the
moorland ants do, but they make up in extent, for
deficiency in height; and by this means the rocks
are gradually covered with soil and vegetation ; for,
on account of the season of the year at which they
build, the growth of the plants keeps pace with the
formation of the ant-soil, and protects it in a great
measure from meteoric abrasion. During the winter,
however, the shape of the ant-hills is' somewhat
modified ; but the matted roots of the plants preserve
the major part of the soil, which will thus remain,
forming an envelope for the rock.

As the annual work of one colony is rarely less

SOIL OR SURFACE-MATTER. 239

than two square feet in superficial area, and sometimes
exceeds a square yard, the yearly work done by a
number of colonies must be very considerable. The
ants that build in the sandy moors seem to frequent
the same spot year after year ; and some of the
hillocks, after a number of years, are of a consider-
able height ; some that were measured in the County
Cork being four feet high, and nearly a yard in
diameter at the base. The ants that build on rocks
appear to occupy generally new places every year;
but perhaps not always, as it has been observed that
in some places the new work has been carried on
in a place where other works had existed in former
years. The rock-covering ants are undoubtedly the
most useful animals of the two; but the others have
also a serviceable place in nature, as they change a
cold unprofitable peat into a workable vegetable soil.
Other soil-producing animals in these countries
are moles, rabbits, rats, mice, foxes, badgers — in fact,
all animals that burrow in the ground, including the
" tillers of the ground." Some do a considerable
quantity of work, while others only act in a small
way. Moles are among the most active workers ; so
are rabbits; the latter often in a great measure helping
to change cliffs into sloping escarpments ; while foxes
and badgers in general do very little work, as they
will rather occupy natural holes than burrow for
themselves.

240

Some soils may be uue to the decay of animal
matter. Off the coast of South America there are
large deposits of guano, which are generally believed
to be due to vast accumulations of the excrements
of birds. It has, however, been shown by the late
Dr J. R. Kinahan that the guano accumulated on
the Chinchas Islands, Peru, are not the excrements of
birds, but " are formed of layers of seals' dung and
decayed seals, the denser, white, thin layers being
made up of the former, and the more friable, darker,
thick layers of the latter," as the sea-lions resort in
hundreds to such places to die. At the same time this
observer does not wish to state all guano is similarly
formed, as the guano from Ichaboe and South Aus-
tralia is so different from that of Peru that they
would seem to have a different origin.*

* Journal of the Royal Dublin Society, July i856, pp. 89 et seq.

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