If a well were sunk at our feet in the midst of the city of Norwich, the
diggers would very soon find themselves at work in that white substance
almost too soft to be called rock, with which we are all familiar as
"chalk."
Not only here, but over the whole county of Norfolk, the well-sinker might
carry his shaft down many hundred feet without coming to the end of the
chalk; and, on the sea-coast, where the waves have pared away the face of
the land which breasts them, the scarped faces of the high cliffs are
often wholly formed of the same material. Northward, the chalk may be
followed as far as Yorkshire; on the south coast it appears abruptly in
the picturesque western bays of Dorset, and breaks into the Needles of the
Isle of Wight;58 while on the shores of Kent it
supplies that long line of white cliffs to which England owes her name of
Albion.
Were the thin soil which covers it all washed away, a curved band of white
chalk, here broader, and there narrower, might be followed diagonally
across England from Lulworth in Dorset, to Flamborough Head 59
in Yorkshire—a distance of over two hundred and eighty miles as the
crow flies.
From this band to the North Sea, on the east, and the Channel, on the
South, the chalk is largely hidden by other deposits; but, except in the
Weald 60
of Kent and Sussex, it enters into the very foundation of all the
south-eastern counties.
Attaining, as it does in some places, a thickness of more than a thousand
feet, the English chalk must be admitted to be a mass of considerable
magnitude. Nevertheless, it covers but an insignificant portion of the
whole area occupied by the chalk formation of the globe, which has
precisely the same general characters as ours, and is found in detached
patches, some less, and others more extensive, than the English.
Chalk occurs in north-west Ireland; it stretches over a large part of
France,—the chalk which underlies Paris being, in fact, a
continuation of that of the London basin; it runs through Denmark and
Central Europe, and extends southward to North Africa; while eastward, it
appears in the Crimea and in Syria, and may be traced as far as the shores
of the Sea of Aral, in Central Asia.
If all the points at which true chalk occurs were circumscribed, they
would lie within an irregular oval about three thousand miles in long
diameter—the area of which would be as great as that of Europe, and
would many times exceed that of the largest existing inland sea—the
Mediterranean.
Thus the chalk is no unimportant element in the masonry of the earth's
crust, and it impresses a peculiar stamp, varying with the conditions to
which it is exposed, on the scenery of the districts in which it occurs.
The undulating downs and rounded coombs, covered with sweet-grassed turf,
of our inland chalk country, have a peacefully domestic and
mutton-suggesting prettiness, but can hardly be called either grand or
beautiful. But on our southern coasts, the wall-sided cliffs, many hundred
feet high, with vast needles and pinnacles standing out in the sea, sharp
and solitary enough to serve as perches for the wary cormorant confer a
wonderful beauty and grandeur upon the chalk headlands. And, in the East,
chalk has its share in the formation of some of the most venerable of
mountain ranges, such as the Lebanon.
What is this wide-spread component of the surface of the earth? and whence
did it come?
You may think this no very hopeful inquiry. You may not unnaturally
suppose that the attempt to solve such problems as these can lead to no
result, save that of entangling the inquirer in vague speculations,
incapable of refutation and of verification.
If such were really the case, I should have selected some other subject
than a "piece of chalk" for my discourse. But, in truth, after much
deliberation, I have been unable to think of any topic which would so well
enable me to lead you to see how solid is the foundation upon which some
of the most startling conclusions of physical science rest.
A great chapter of the history of the world is written in the chalk. Few
passages in the history of man can be supported by such an overwhelming
mass of direct and indirect evidence as that which testifies to the truth
of the fragment of the history of the globe, which I hope to enable you to
read, with your own eyes, tonight.
Let me add, that few chapters of human history have a more profound
significance for ourselves. I weigh my words well when I assert, that the
man who should know the true history of the bit of chalk which every
carpenter carries about in his breeches-pocket, though ignorant of all
other history, is likely, if he will think his knowledge out to its
ultimate results, to have a truer, and therefore a better, conception of
this wonderful universe, and of man's relation to it, than the most
learned student who is deep-read in the records of humanity and ignorant
of those of Nature.
The language of the chalk is not hard to learn, not nearly so hard as
Latin, if you only want to get at the broad features of the story it has
to tell; and I propose that we now set to work to spell that story out
together.
We all know that if we "burn" chalk the result is quicklime. Chalk, in
fact, is a compound of carbonic acid gas, and lime, and when you make it
very hot the carbonic acid flies away and the lime is left.
By this method of procedure we see the lime, but we do not see the
carbonic acid. If, on the other hand, you were to powder a little chalk
and drop it into a good deal of strong vinegar, there would be a great
bubbling and fizzing, and, finally, a clear liquid, in which no sign of
chalk would appear. Here you see the carbonic acid in the bubbles; the
lime, dissolved in the vinegar, vanishes from sight. There are a great
many other ways of showing that chalk is essentially nothing but carbonic
acid and quicklime. Chemists enunciate the result of all the experiments
which prove this, by stating that chalk is almost wholly composed of
"carbonate of lime."
It is desirable for us to start from the knowledge of this fact, though it
may not seem to help us very far towards what we seek. For carbonate of
lime is a widely spread substance, and is met with under very various
conditions. All sorts of limestones are composed of more or less pure
carbonate of lime. The crust which is often deposited by waters which have
drained through limestone rocks, in the form of what are called
stalagmites and stalactites, is carbonate of lime. Or, to take a more
familiar example, the fur on the inside of a tea-kettle is carbonate of
lime; and, for anything chemistry tells us to the contrary, the chalk
might be a kind of gigantic fur upon the bottom of the earth-kettle, which
is kept pretty hot below.
Let us try another method of making the chalk tell us its own history. To
the unassisted eye chalk looks simply like a very loose and open kind of
stone. But it is possible to grind a slice of chalk down so thin that you
can see through it—until it is thin enough, in fact, to be examined
with any magnifying power that may be thought desirable. A thin slice of
the fur of a kettle might be made in the same way. If it were examined
microscopically, it would show itself to be a more or less distinctly
laminated mineral substance and nothing more.
But the slice of chalk presents a totally different appearance when placed
under the microscope. The general mass of it is made up of very minute
granules; but, imbedded in this matrix, are innumerable bodies, some
smaller and some larger, but, on a rough average, not more than a
hundredth of an inch in diameter, having a well-defined shape and
structure. A cubic inch of some specimens of chalk may contain hundreds of
thousands of these bodies, compacted together with incalculable millions
of the granules.
The examination of a transparent slice gives a good notion of the manner
in which the components of the chalk are arranged, and of their relative
proportions. But, by rubbing up some chalk with a brush in water and then
pouring off the milky fluid, so as to obtain sediments of different
degrees of fineness, the granules and the minute rounded bodies may be
pretty well separated from one another, and submitted to microscopic
examination, either as opaque or as transparent objects. By combining the
views obtained in these various methods, each of the rounded bodies may be
proved to be a beautifully constructed calcareous fabric, made up of a
number of chambers, communicating freely with one another. The chambered
bodies are of various forms. One of the commonest is something like a
badly grown raspberry, being formed of a number of nearly globular
chambers of different sizes congregated together. It is called
Globigerina, and some specimens of chalk consist of little else than
Globigerina and granules.
Let us fix our attention upon the Globigerina. It is the spoor of the game
we are tracking. If we can learn what it is and what are the conditions of
its existence, we shall see our way to the origin and past history of the
chalk.
A suggestion which may naturally enough present itself is, that these
curious bodies are the result of some process of aggregation which has
taken place in the carbonate of lime; that, just as in winter, the rime on
our windows simulates the most delicate and elegantly arborescent foliage—proving
that the mere mineral water may, under certain conditions, assume the
outward form of organic bodies—so this mineral substance, carbonate
of lime, hidden away in the bowels of the earth, has taken the shape of
these chambered bodies. I am not raising a merely fanciful and unreal
objection. Very learned men, in former days, have even entertained the
notion that all the formed things found in rocks are of this nature; and
if no such conception is at present held to be admissible, it is because
long and varied experience has now shown that mineral matter never does
assume the form and structure we find in fossils. If any one were to try
to persuade you that an oyster-shell (which is also chiefly composed of
carbonate of lime) had crystallized out of sea-water, I suppose you would
laugh at the absurdity. Your laughter would be justified by the fact that
all experience tends to show that oyster-shells are formed by the agency
of oysters, and in no other way. And if there were no better reasons, we
should be justified, on like grounds, in believing that Globigerina is not
the product of anything but vital activity.
Happily, however, better evidence in proof of the organic nature of the
Globigerinae than that of analogy is forthcoming. It so happens that
calcareous skeletons, exactly similar to the Globigerinae of the chalk,
are being formed, at the present moment, by minute living creatures, which
flourish in multitudes, literally more numerous than the sands of the
sea-shore, over a large extent of that part of the earth's surface which
is covered by the ocean.
The history of the discovery of these living Globigerinae, and of the part
which they play in rock building, is singular enough. It is a discovery
which, like others of no less scientific importance, has arisen,
incidentally, out of work devoted to very different and exceedingly
practical interests.
When men first took to the sea, they speedily learned to look out for
shoals and rocks; and the more the burthen of their ships increased, the
more imperatively necessary it became for sailors to ascertain with
precision the depths of the waters they traversed. Out of this necessity
grew the use of the lead and sounding line; and, ultimately,
marine-surveying, which is the recording of the form of coasts and of the
depth of the sea, as ascertained by the sounding-lead, upon charts.
At the same time, it became desirable to ascertain and to indicate the
nature of the sea-bottom, since this circumstance greatly affects its
goodness as holding ground for anchors. Some ingenious tar, whose name
deserves a better fate than the oblivion into which it has fallen,
attained this object by "arming" the bottom of the lead with a lump of
grease, to which more or less of the sand or mud, or broken shells, as the
case might be, adhered, and was brought to the surface. But, however well
adapted such an apparatus might be for rough nautical purposes, scientific
accuracy could not be expected from the armed lead, and to remedy its
defects (especially when applied to sounding in great depths) Lieut.
Brooke,61
of the American Navy, some years ago invented a most ingenious machine, by
which a considerable portion of the superficial layer of the sea-bottom
can be scooped out and brought up from any depth to which the lead
descends.
In 1853, Lieut. Brooke obtained mud from the bottom of the North Atlantic,
between Newfoundland and the Azores, at a depth of more than ten thousand
feet, or two miles, by the help of this sounding apparatus. The specimens
were sent for examination to Ehrenberg 62 of Berlin,
and to Bailey of West Point,63 and those able microscopists
found that this deep-sea mud was almost entirely composed of the skeletons
of living organisms—the greater proportion of these being just like
the Globigerinae already known to occur in the chalk.
Thus far, the work had been carried on simply in the interests of science,
but Lieut. Brooke's method of sounding acquired a high commercial value,
when the enterprise of laying down the telegraph-cable 64
between this country and the United States was undertaken. For it became a
matter of immense importance to know, not only the depth of the sea over
the whole line along which the cable was to be laid, but the exact nature
of the bottom, so as to guard against chances of cutting or fraying the
strands of that costly rope. The Admiralty consequently ordered Captain
Dayman, an old friend and shipmate of mine, to ascertain the depth over
the whole line of the cable, and to bring back specimens of the bottom. In
former days, such a command as this might have sounded very much like one
of the impossible things which the young prince in the Fairy Tales is
ordered to do before he can obtain the hand of the Princess. However, in
the months of June and July, 1857, my friend performed the task assigned
to him with great expedition and precision without, so far as I know,
having met with any reward of that kind. The specimens of Atlantic mud
which he procured were sent to me to be examined and reported upon.*
The result of all these operations is, that we know the contours and the
nature of the surface-soil covered by the North Atlantic, for a distance
of seventeen hundred miles from east to west, as well as we know that of
any part of the dry land.
It is a prodigious plain—one of the widest and most even plains in
the world. If the sea were drained off, you might drive a wagon all the
way from Valentia, on the west coast of Ireland, to Trinity Bay, in
Newfoundland. And, except upon one sharp incline about two hundred miles
from Valentia, I am not quite sure that it would even be necessary to put
the skid on, so gentle are the ascents and descents upon that long route.
From Valentia the road would lie down-hill for about 200 miles to the
point at which the bottom is now covered by 1700 fathoms of sea-water.
Then would come the central plain, more than a thousand miles wide, the
inequalities of the surface of which would be hardly perceptible, though
the depth of water upon it now varies from 10,000 to 15,000 feet; and
there are places in which Mont Blanc might be sunk without showing its
peak above water. Beyond this, the ascent on the American side commences,
and gradually leads, for about 300 miles, to the Newfoundland shore.
Almost the whole of the bottom of this central plain (which extends for
many hundred miles in a north and south direction) is covered by a fine
mud, which, when brought to the surface, dries into a greyish-white
friable substance. You can write with this on a blackboard, if you are so
inclined; and, to the eye, it is quite like very soft, greyish chalk.
Examined chemically, it proves to be composed almost wholly of carbonate
of lime; and if you make a section of it, in the same way as that of the
piece of chalk was made, and view it with the microscope, it presents
innumerable Globigerinae embedded in a granular matrix.
Thus this deep-sea mud is substantially chalk. I say substantially,
because there are a good many minor differences; but as these have no
bearing on the question immediately before us,—which is the nature
of the Globigerinae of the chalk,—it is unnecessary to speak of
them.
Globigerinae of every size, from the smallest to the largest, are
associated together in the Atlantic mud, and the chambers of many are
filled by a soft animal matter. This soft substance is, in fact, the
remains of the creature to which the Globigerina shell, or rather
skeleton, owes its existence—and which is an animal of the simplest
imaginable description. It is, in fact, a mere particle of living jelly,
without defined parts of any kind—without a mouth, nerves, muscles,
or distinct organs, and only manifesting its vitality to ordinary
observation by thrusting out and retracting from all parts of its surface,
long filamentous processes, which serve for arms and legs. Yet this
amorphous particle, devoid of everything which, in the higher animals, we
call organs, is capable of feeding, growing and multiplying; of separating
from the ocean the small proportion of carbonate of lime which is
dissolved in sea-water; and of building up that substance into a skeleton
for itself, according to a pattern which can be imitated by no other known
agency.
The notion that animals can live and flourish in the sea, at the vast
depths from which apparently living Globigerinae have been brought up,
does not agree very well with our usual conceptions respecting the
conditions of animal life; and it is not so absolutely impossible as it
might at first appear to be, that the Globigerinae of the Atlantic
sea-bottom do not live and die where they are found.
As I have mentioned, the soundings from the great Atlantic plain are
almost entirely made up of Globigerinae, with the granules which have been
mentioned and some few other calcareous shells; but a small percentage of
the chalky mud—perhaps at most some five per cent of it—is of
a different nature, and consists of shells and skeletons composed of
silex, or pure flint. These silicious bodies belong partly to the lowly
vegetable organisms which are called Diatomaceae, and partly to the
minute, and extremely simple, animals, termed Radiolaria. It is quite
certain that these creatures do not live at the bottom of the ocean, but
at its surface—where they may be obtained in prodigious numbers by
the use of a properly constructed net. Hence it follows that these
silicious organisms, though they are not heavier than the lightest dust,
must have fallen, in some cases, through fifteen thousand feet of water,
before they reached their final resting-place on the ocean floor. And,
considering how large a surface these bodies expose in proportion to their
weight, it is probable that they occupy a great length of time in making
their burial journey from the surface of the Atlantic to the bottom.
But if the Radiolaria and Diatoms are thus rained upon the bottom of the
sea, from the superficial layer of its waters in which they pass their
lives, it is obviously possible that the Globigerinae may be similarly
derived; and if they were so, it would be much more easy to understand how
they obtain their supply of food than it is at present. Nevertheless, the
positive and negative evidence all points the other way. The skeletons of
the full-grown, deep-sea Globigerinae are so remarkably solid and heavy in
proportion to their surface as to seem little fitted for floating; and, as
a matter of fact, they are not to be found along with the Diatoms and
Radiolaria, in the uppermost stratum of the open ocean.
It has been observed, again, that the abundance of Globigerinae, in
proportion to other organisms, of like kind, increases with the depth of
the sea; and that deep-water Globigerinae are larger than those which live
in shallower parts of the sea; and such facts negative the supposition
that these organisms have been swept by currents from the shallows into
the deeps of the Atlantic.
It therefore seems to be hardly doubtful that these wonderful creatures
live and die at the depths in which they are found.
However, the important points for us are, that the living Globigerinae are
exclusively marine animals, the skeletons of which abound at the bottom of
deep seas; and that there is not a shadow of reason for believing that the
habits of the Globigerinae of the chalk differed from those of the
existing species. But if this be true, there is no escaping the conclusion
that the chalk itself is the dried mud of an ancient deep sea.
In working over the soundings collected by Captain Dayman, I was surprised
to find that many of what I have called the "granules" of that mud, were
not, as one might have been tempted to think at first, the mere powder and
waste of Globigerinae, but that they had a definite form and size. I
termed these bodies "coccoliths," and doubted their organic nature. Dr.
Wallich 65
verified my observation, and added the interesting discovery, that, not
unfrequently, bodies similar to these "coccoliths" were aggregated
together into spheroids, which he termed "coccospheres." So far as we
knew, these bodies, the nature of which is extremely puzzling and
problematical, were peculiar to the Atlantic soundings.
But, a few years ago, Mr. Sorby,66 in making
a careful examination of the chalk by means of thin sections and
otherwise, observed, as Ehrenberg had done before him, that much of its
granular basis possesses a definite form. Comparing these formed particles
with those in the Atlantic soundings, he found the two to be identical;
and thus proved that the chalk, like the soundings, contains these
mysterious coccoliths and coccospheres. Here was a further and a most
interesting confirmation, from internal evidence, of the essential
identity of the chalk with modern deep-sea mud. Globigerinae, coccoliths,
and coccospheres are round as the chief constituents of both, and testify
to the general similarity of the conditions under which both have been
formed.
The evidence furnished by the hewing, facing, and superposition of the
stones of the Pyramids, that these structures were built by men, has no
greater weight than the evidence that the chalk was built by Globigerinae;
and the belief that those ancient pyramid-builders were terrestrial and
air-breathing creatures like ourselves, is it not better based than the
conviction that the chalk-makers lived in the sea?
But as our belief in the building of the Pyramids by men is not only
grounded on the internal evidences afforded by these structures, but
gathers strength from multitudinous collateral proofs, and is clinched by
the total absence of any reason for a contrary belief; so the evidence
drawn from the Globigerinae that the chalk is an ancient sea-bottom, is
fortified by innumerable independent lines of evidence; and our belief in
the truth of the conclusion to which all positive testimony tends,
receives the like negative justification from the fact that no other
hypothesis has a shadow of foundation.
It may be worth while briefly to consider a few of these collateral proofs
that the chalk was deposited at the bottom of the sea.
The great mass of the chalk is composed, as we have seen, of the skeletons
of Globigerinae, and other simple organisms, imbedded in granular matter.
Here and there, however, this hardened mud of the ancient sea reveals the
remains of higher animals which have lived and died, and left their hard
parts in the mud, just as the oysters die and leave their shells behind
them, in the mud of the present seas.
There are, at the present day, certain groups of animals which are never
found in fresh waters, being unable to live anywhere but in the sea. Such
are the corals; those corallines which are called Polycoa; those creatures
which fabricate the lamp-shells, and are called Brachiopoda; the pearly
Nautilus, and all animals allied to it; and all the forms of sea-urchins
and star-fishes.
Not only are all these creatures confined to salt water at the present
day; but, so far as our records of the past go, the conditions of their
existence have been the same: hence, their occurrence in any deposit is as
strong evidence as can be obtained, that that deposit was formed in the
sea. Now the remains of animals of all the kinds which have been
enumerated, occur in the chalk, in greater or less abundance; while not
one of those forms of shell-fish which are characteristic of fresh water
has yet been observed in it.
When we consider that the remains of more than three thousand distinct
species of aquatic animals have been discovered among the fossils of the
chalk, that the great majority of them are of such forms as are now met
with only in the sea, and that there is no reason to believe that any one
of them inhabited fresh water—the collateral evidence that the chalk
represents an ancient sea-bottom acquires as great force as the proof
derived from the nature of the chalk itself. I think you will now allow
that I did not overstate my case when I asserted that we have as strong
grounds for believing that all the vast area of dry land, at present
occupied by the chalk, was once at the bottom of the sea, as we have for
any matter of history whatever; while there is no justification for any
other belief.
No less certain it is that the time during which the countries we now call
south-east England, France, Germany, Poland, Russia, Egypt, Arabia, Syria,
were more or less completely covered by a deep sea, was of considerable
duration.
We have already seen that the chalk is, in places, more than a thousand
feet thick. I think you will agree with me, that it must have taken some
time for the skeletons of animalcules of a hundredth of an inch in
diameter to heap up such a mass as that. I have said that throughout the
thickness of the chalk the remains of other animals are scattered. These
remains are often in the most exquisite state of preservation. The valves
of the shell-fishes are commonly adherent; the long spines of some of the
sea-urchins, which would be detached by the smallest jar, often remain in
their places. In a word, it is certain that these animals have lived and
died when the place which they now occupy was the surface of as much of
the chalk as had then been deposited; and that each has been covered up by
the layer of Globigerina mud, upon which the creatures imbedded a little
higher up have, in like manner, lived and died. But some of these remains
prove the existence of reptiles of vast size in the chalk sea. These lived
their time, and had their ancestors and descendants, which assuredly
implies time, reptiles being of slow growth.
There is more curious evidence, again, that the process of covering up,
or, in other words, the deposit of Globigerina skeletons, did not go on
very fast. It is demonstrable that an animal of the cretaceous sea might
die, that its skeleton might lie uncovered upon the sea-bottom long enough
to lose all its outward coverings and appendages by putrefaction; and
that, after this had happened, another animal might attach itself to the
dead and naked skeleton, might grow to maturity, and might itself die
before the calcareous mud had buried the whole.
Cases of this kind are admirably described by Sir Charles Lyell.67
He speaks of the frequency with which geologists find in the chalk a
fossilized sea-urchin, to which is attached the lower valve of a Crania.
This is a kind of shell-fish, with a shell composed of two pieces, of
which, as in the oyster, one is fixed and the other free.
"The upper valve is almost invariably wanting, though occasionally found
in a perfect state of preservation in the white chalk at some distance. In
this case, we see clearly that the sea-urchin first lived from youth to
age, then died and lost its spines, which were carried away. Then the
young Crania adhered to the bared shell, grew and perished in its turn;
after which, the upper valve was separated from the lower, before the
Echinus 68
became enveloped in chalky mud."
A specimen in the Museum of Practical Geology, in London, still further
prolongs the period which must have elapsed between the death of the
sea-urchin, and its burial by the Globigerinae. For the outward face of
the valve of a Crania, which is attached to a sea-urchin (Micraster), is
itself overrun by an incrusting coralline, which spreads thence over more
or less of the surface of the sea-urchin. It follows that, after the upper
valve of the Crania fell off, the surface of the attached valve must have
remained exposed long enough to allow of the growth of the whole
corraline, since corallines do not live imbedded in mud.
The progress of knowledge may, one day, enable us to deduce from such
facts as these the maximum rate at which the chalk can have accumulated,
and thus to arrive at the minimum duration of the chalk period. Suppose
that the valve of the Crania upon which a coralline has fixed itself in
the way just described, is so attached to the sea-urchin that no part of
it is more than an inch above the face upon which the sea-urchin rests.
Then, as the coralline could not have fixed itself, if the Crania had been
covered up with chalk mud, and could not have lived had itself been so
covered it follows, that an inch of chalk mud could not have accumulated
within the time between the death and decay of the soft parts of the
sea-urchin and the growth of the coralline to the full size which it has
attained. If the decay of the soft parts of the sea-urchin; the
attachment, growth to maturity, and decay of the Crania; and the
subsequent attachment and growth of the coralline, took a year (which is a
low estimate enough), the accumulation of the inch of chalk must have
taken more than a year: and the deposit of a thousand feet of chalk must,
consequently, have taken more than twelve thousand years.
The foundation of all this calculation is, of course, a knowledge of the
length of time the Crania and the coralline needed to attain their full
size; and, on this head, precise knowledge is at present wanting. But
there are circumstances which tend to show, that nothing like an inch of
chalk has accumulated during the life of a Crania; and, on any probable
estimate of the length of that life, the chalk period must have had a much
longer duration than that thus roughly assigned to it.
Thus, not only is it certain that the chalk is the mud of an ancient
sea-bottom; but it is no less certain, that the chalk sea existed during
an extremely long period, though we may not be prepared to give a precise
estimate of the length of that period in years. The relative duration is
clear, though the absolute duration may not be definable. The attempt to
affix any precise date to the period at which the chalk sea began, or
ended, its existence, is baffled by difficulties of the same kind. But the
relative age of the cretaceous epoch may be determined with as great ease
and certainty as the long duration of that epoch.
You will have heard of the interesting discoveries recently made, in
various parts of Western Europe, of flint implements, obviously worked
into shape by human hands, under circumstances which show conclusively
that man is a very ancient denizen of these regions.
It has been proved that the old populations of Europe, whose existence has
been revealed to us in this way, consisted of savages, such as the
Esquimaux are now; that, in the country which is now France, they hunted
the reindeer, and were familiar with the ways of the mammoth and the
bison. The physical geography of France was in those days different from
what it is now—the river Somme,69 for
instance, having cut its bed a hundred feet deeper between that time and
this; and, it is probable, that the climate was more like that of Canada
or Siberia, than that of Western Europe.
The existence of these people is forgotten even in the traditions of the
oldest historical nations. The name and fame of them had utterly vanished
until a few years back; and the amount of physical change which has been
effected since their day, renders it more than probable that, venerable as
are some of the historical nations, the workers of the chipped flints of
Hoxne or of Amiens 70 are to them, as they are to us,
in point of antiquity.
But, if we assign to these hoar relics of long-vanished generations of men
the greatest age that can possibly be claimed for them, they are not older
than the drift, or boulder clay, which, in comparison with the chalk, is
but a very juvenile deposit. You need go no further than your own
sea-board for evidence of this fact. At one of the most charming spots on
the coast of Norfolk, Cromer, you will see the boulder clay forming a vast
mass, which lies upon the chalk, and must consequently have come into
existence after it. Huge boulders of chalk are, in fact, included in the
clay, and have evidently been brought to the position they now occupy, by
the same agency as that which has planted blocks of syenite from Norway
side by side with them.
The chalk, then, is certainly older than the boulder clay. If you ask how
much, I will again take you no further than the same spot upon your own
coasts for evidence. I have spoken of the boulder clay and drift as
resting upon the chalk. That is not strictly true. Interposed between the
chalk and the drift is a comparatively insignificant layer, containing
vegetable matter. But that layer tells a wonderful history. It is full of
stumps of trees standing as they grew. Fir-trees are there with their
cones, and hazel-bushes with their nuts; there stand the stools of oak and
yew trees, beeches and alders. Hence this stratum is appropriately called
the "forest-bed."
It is obvious that the chalk must have been up-heaved and converted into
dry land, before the timber trees could grow upon it. As the boles of some
of these trees are from two to three feet in diameter, it is no less clear
that the dry land this formed remained in the same condition for long
ages. And not only do the remains of stately oaks and well-grown firs
testify to the duration of this condition of things, but additional
evidence to the same effect is afforded by the abundant remains of
elephants, rhinoceroses, hippopotomuses and other great wild beasts, which
it has yielded to the zealous search of such men as the Rev. Mr. Gunn.71
When you look at such a collection as he has formed, and bethink you that
these elephantine bones did veritably carry their owners about, and these
great grinders crunch, in the dark woods of which the forest-bed is now
the only trace, it is impossible not to feel that they are as good
evidence of the lapse of time as the annual rings of the tree-stumps.
Thus there is a writing upon the walls of cliffs at Cromer, and whoso runs
may read it. It tells us, with an authority which cannot be impeached,
that the ancient sea-bed of the chalk sea was raised up, and remained dry
land, until it was covered with forest, stocked with the great game whose
spoils have rejoiced your geologists. How long it remained in that
condition cannot be said; but "the whirligig of time 72 brought
its revenges" in those days as in these. That dry land, with the bones and
teeth of generations of long-lived elephants, hidden away among the
gnarled roots and dry leaves of its ancient trees, sank gradually to the
bottom of the icy sea, which covered it with huge masses of drift and
boulder clay. Sea-beasts, such as the walrus, now restricted to the
extreme north, paddled about where birds had twittered among the topmost
twigs of the fir-trees. How long this state of things endured we know not,
but at length it came to an end. The upheaved glacial mud hardened into
the soil of modern Norfolk. Forests grew once more, the wolf and the
beaver replaced the reindeer and the elephant; and at length what we call
the history of England dawned.
Thus you have within the limits of your own county, proof that the chalk
can justly claim a very much greater antiquity than even the oldest
physical traces of mankind. But we may go further and demonstrate, by
evidence of the same authority as that which testifies to the existence of
the father of men, that the chalk is vastly older than Adam himself.
The Book of Genesis informs us that Adam, immediately upon his creation,
and before the appearance of Eve, was placed in the Garden of Eden. The
problem of the geographical position of Eden has greatly vexed the spirits
of the learned in such matters, but there is one point respecting which,
so far as I know, no commentator has ever raised a doubt. This is, that of
the four rivers which are said to run out of it, Euphrates and Hiddekel 73
are identical with the rivers now known by the names of Euphrates and
Tigris.
But the whole country in which these mighty rivers take their origin, and
through which they run, is composed of rocks which are either of the same
age as the chalk, or of later date. So that the chalk must not only have
been formed, but, after its formation, the time required for the deposit
of these later rocks, and for their upheaval into dry land, must have
elapsed, before the smallest brook which feeds the swift stream of "the
great river, the river of Babylon,"74 began to
flow.
Thus, evidence which cannot be rebutted, and which need not be
strengthened, though if time permitted I might indefinitely increase its
quantity, compels you to believe that the earth, from the time of the
chalk to the present day, has been the theatre of a series of changes as
vast in their amount, as they were slow in their progress. The area on
which we stand has been first sea and then land, for at least four
alternations; and has remained in each of these conditions for a period of
great length.
Nor have these wonderful metamorphoses of sea into land, and of land into
sea, been confined to one corner of England. During the chalk period, or
"cretaceous epoch," not one of the present great physical features of the
globe was in existence. Our great mountain ranges, Pyrenees, Alps,
Himalayas, Andes, have all been upheaved since the chalk was deposited,
and the cretaceous sea flowed over the sites of Sinai and Ararat.
All this is certain, because rocks of cretaceous, or still later, date
have shared in the elevatory movements which gave rise to these mountain
chains; and may be found perched up, in some cases, many thousand feet
high upon their flanks. And evidence of equal cogency demonstrates that,
though, in Norfolk, the forest-bed rests directly upon the chalk, yet it
does so, not because the period at which the forest grew immediately
followed that at which the chalk was formed, but because an immense lapse
of time, represented elsewhere by thousands of feet of rock, is not
indicated at Cromer.
I must ask you to believe that there is no less conclusive proof that a
still more prolonged succession of similar changes occurred, before the
chalk was deposited. Nor have we any reason to think that the first term
in the series of these changes is known. The oldest sea-beds preserved to
us are sands, and mud, and pebbles, the wear and tear of rocks which were
formed in still older oceans.
But, great as is the magnitude of these physical changes of the world,
they have been accompanied by a no less striking series of modifications
in its living inhabitants.
All the great classes of animals, beasts of the field, fowls of the air,
creeping things, and things which dwell in the waters, flourished upon the
globe long ages before the chalk was deposited. Very few, however, if any,
of these ancient forms of animal life were identical with those which now
live. Certainly not one of the higher animals was of the same species as
any of those now in existence. The beasts of the field, in the days before
the chalk, were not our beasts of the field, nor the fowls of the air such
as those which the eye of men has seen flying, unless his antiquity dates
infinitely further back than we at present surmise. If we could be carried
back into those times, we should be as one suddenly set down in Australia
before it was colonized. We should see mammals, birds, reptiles, fishes,
insects, snails, and the like, clearly recognisable as such, and yet not
one of them would be just the same as those with which we are familiar,
and many would be extremely different.
From that time to the present, the population of the world has undergone
slow and gradual, but incessant changes. There has been no grand
catastrophe—no destroyer has swept away the forms of life of one
period, and replaced them by a totally new creation; but one species has
vanished and another has taken its place; creatures of one type of
structure have diminished, those of another have increased, as time has
passed on. And thus, while the differences between the living creatures of
the time before the chalk and those of the present day appear startling,
if placed side by side, we are led from one to the other by the most
gradual progress, if we follow the course of Nature through the whole
series of those relics of her operations which she has left behind.
And it is by the population of the chalk sea that the ancient and the
modern inhabitants of the world are most completely connected. The groups
which are dying out flourish, side by side, with the groups which are now
the dominant forms of life.
Thus the chalk contains remains of those strange flying and swimming
reptiles, the pterodactyl, the ichthyosaurus, and the plesiosaurus, which
are found in no later deposits, but abounded in preceding ages. The
chambered shells called ammonites and belemnites, which are so
characteristic of the period preceding the cretaceous, in like manner die
with it.
But, amongst these fading remainders of a previous state of things, are
some very modern forms of life, looking like Yankee pedlars among a tribe
of Red Indians. Crocodiles of modern type appear; bony fishes, many of
them very similar to existing species almost supplant the forms of fish
which predominate in more ancient seas; and many kinds of living shellfish
first become known to us in the chalk. The vegetation acquires a modern
aspect. A few living animals are not even distinguishable as species, from
those which existed at that remote epoch. The Globigerina of the present
day, for example, is not different specifically from that of the chalk;
and the same may be said of many other Foraminifera. I think it probable
that critical and unprejudiced examination will show that more than one
species of much higher animals have had a similar longevity; but the only
example, which I can at present give confidently is the snake's-head
lamp-shell (Terebratulina caput serpentis), which lives in our English
seas and abounded (as Terebratulina striata of authors) in the chalk.
The longest line of human ancestry must hide its diminished head before
the pedigree of this insignificant shell-fish. We Englishmen are proud to
have an ancestor who was present at the Battle of Hastings. The ancestors
of Terebratulina caput serpentis may have been present at a battle of
Ichthyosauria in that part of the sea which, when the chalk was forming,
flowed over the site of Hastings. While all around has changed, this
Terebratulina has peacefully propagated its species from generation to
generation, and stands to this day, as a living testimony to the
continuity of the present with the past history of the globe.
Up to this moment I have stated, so far as I know, nothing but
well-authenticated facts, and the immediate conclusions which they force
upon the mind.
But the mind is so constituted that it does not willingly rest in facts
and immediate causes, but seeks always after a knowledge of the remoter
links in the chain of causation.
Taking the many changes of any given spot of the earth's surface, from sea
to land and from land to sea, as an established fact, we cannot refrain
from asking ourselves how these changes have occurred. And when we have
explained them—as they must be explained—by the alternate slow
movements of elevation and depression which have affected the crust of the
earth, we go still further back, and ask, Why these movements?
I am not certain that any one can give you a satisfactory answer to that
question. Assuredly I cannot. All that can be said, for certain, is, that
such movements are part of the ordinary course of nature, inasmuch as they
are going on at the present time. Direct proof may be given, that some
parts of the land of the northern hemisphere are at this moment insensibly
rising and others insensibly sinking; and there is indirect, but perfectly
satisfactory, proof, that an enormous area now covered by the Pacific has
been deepened thousands of feet, since the present inhabitants of that sea
came into existence.
Thus there is not a shadow of a reason for believing that the physical
changes of the globe, in past times have been effected by other than
natural causes.
Is there any more reason for believing that the concomitant modifications
in the forms of the living inhabitants of the globe have been brought
about in other ways?
Before attempting to answer this question, let us try to form a distinct
mental picture of what has happened, in some special case.
The crocodiles are animals which, as a group, have a very vast antiquity.
They abounded ages before the chalk was deposited; they throng the rivers
in warm climates, at the present day. There is a difference in the form of
the joints of the back-bone, and in some minor particulars, between the
crocodiles of the present epoch and those which lived before the chalk;
but in the cretaceous epoch, as I have already mentioned, the crocodiles
had assumed the modern type of structure. Notwithstanding this, the
crocodiles of the chalk are not identically the same as those which lived
in the times called "older tertiary," which succeeded the cretaceous
epoch; and the crocodiles of the older tertiaries are not identical with
those of the newer tertiaries, nor are these identical with existing
forms. I leave open the question whether particular species may have lived
on from epoch to epoch. But each epoch has had its peculiar crocodiles;
though all, since the chalk, have belonged to the modern type, and differ
simply in their proportions, and in such structural particulars as are
discernible only to trained eyes.
How is the existence of this long succession of different species of
crocodiles to be accounted for?
Only two suppositions seem to be open to us—Either each species of
crocodile has been specially created, or it has arisen out of some
pre-existing form by the operation of natural causes.
Choose your hypothesis; I have chosen mine. I can find no warranty for
believing in the distinct creation of a score of successive species of
crocodiles in the course of countless ages of time. Science gives no
countenance to such a wild fancy; nor can even the perverse ingenuity of a
commentator pretend to discover this sense, in the simple words in which
the writer of Genesis records the proceedings of the fifth and sixth days
of the Creation.
On the other hand, I see no good reason for doubting the necessary
alternative, that all these varied species have been evolved from
pre-existing crocodilian forms, by the operation of causes as completely a
part of the common order of nature, as those which have effected the
changes of the inorganic world.
Few will venture to affirm that the reasoning which applies to crocodiles
loses its force among other animals, or among plants. If one series of
species has come into existence by the operation of natural causes, it
seems folly to deny that all may have arisen in the same way.
A small beginning has led us to a great ending. If I were to put the bit
of chalk with which we started into the hot but obscure flame of burning
hydrogen, it would presently shine like the sun. It seems to me that this
physical metamorphosis is no false image of what has been the result of
our subjecting it to a jet of fervent, though nowise brilliant, thought
to-night. It has become luminous, and its clear rays, penetrating the
abyss of the remote past, have brought within our ken some stages of the
evolution of the earth. And in the shifting "without haste, but without
rest"75
of the land and sea, as in the endless variation of the forms assumed by
living beings, we have observed nothing but the natural product of the
forces originally possessed by the substance of the universe.
