§ 2
The Geological
Time-table
The long history of the earth and its
inhabitants is conveniently divided into eras. Thus, just as we speak of the
ancient, mediæval, and modern history of mankind, so we may speak of Palæozoic,
Mesozoic and Cenozoic eras in the history of the earth as a whole.
Geologists
cannot tell us except in an approximate way how long the process of evolution
has taken. One of the methods is to estimate how long has been required for the
accumulation of the salts of the sea, for all these have been dissolved out of
the rocks since rain began to fall on the earth. Dividing the total amount of
saline matter by what is contributed every year in modern times, we get about a
hundred million years as the age of the sea. But as the present rate of
salt-accumulation is probably much greater than it was during many of the
geological periods, the prodigious age just mentioned is in all likelihood far
below the mark. Another method is to calculate how long it would take to form
the sedimentary rocks, like sandstones and mudstones, which have a total
thickness of over fifty miles, though the local thickness is rarely over
a mile. As most of the materials have come from the weathering of the earth's
crust, and as the annual amount of weathering now going on can be estimated,
the time required for the formation of the sedimentary rocks of the world can
be approximately calculated. There are some other ways of trying to tell the
earth's age and the length of the successive periods, but no certainty has been
reached.
The eras marked on the table (page 92) as before
the Cambrian correspond to about thirty-two miles of thickness of strata;
and all the subsequent eras with fossil-bearing rocks to a thickness of about
twenty-one miles, in itself an astounding fact. Perhaps thirty million years
must be allotted to the Pre-Cambrian eras, eighteen to the Palæozoic, nine to
the Mesozoic, three to the Cenozoic, making a grand total of sixty millions.
The Establishment of
Invertebrate Stocks
It is an astounding fact that at least half
of geological time (the Archæozoic and Proterozoic eras) passed before there
were living creatures with parts sufficiently hard to form fossils. In the
latter part of the Proterozoic era there are traces of one-celled marine
animals (Radiolarians) with shells of flint, and of worms that wallowed in the
primal mud. It is plain that as regards the most primitive creatures the rock
record tells us little.
/The%20Outline%20of%20Science%20-%20Story%20of%20Evolution_files/image154a_sm.jpg "ANIMALS OF THE CAMBRIAN PERIOD")
From Knipe's "Nebula to Man."
ANIMALS OF THE CAMBRIAN PERIOD
e.g. Sponges, Jellyfish, Starfish, Sea-lilies, Water-fleas, and Trilobites
/The%20Outline%20of%20Science%20-%20Story%20of%20Evolution_files/image154b_sm.jpg "A TRILOBITE")
Photo: J. J. Ward, F.E.S.
A TRILOBITE
Trilobites were ancient seashore animals, abundant from the Upper
Cambrian to the Carboniferous eras. They have no direct descendants to-day.
They were jointed-footed animals, allied to Crustaceans and perhaps also to
King-crabs. They were able to roll themselves up in their ring-armour.
/The%20Outline%20of%20Science%20-%20Story%20of%20Evolution_files/image155a_sm.jpg "THE GAMBIAN MUD-FISH, PROTOPTERUS")
Photo: British Museum (Natural History).
THE GAMBIAN MUD-FISH, PROTOPTERUS
It can breathe oxygen dissolved in water by its gills; it can
also breathe dry air by means of its swim-bladder, which has become a lung. It
is a double-breather, showing evolution in process. For seven months of
the year, the dry season, it can remain inert in the mud, getting air through
an open pipe to the surface. When water fills the pools it can use its gills
again. Mud-nests or mud encasements with the lung-fish inside have often been
brought to Britain and the fish when liberated were quite lively.
/The%20Outline%20of%20Science%20-%20Story%20of%20Evolution_files/image155b_sm.jpg "THE ARCHÆOPTERYX")
THE ARCHÆOPTERYX
(After William Leche of Stockholm.)
A good restoration of the oldest known bird, Archæopteryx
(Jurassic Era). It was about the size of a crow; it had teeth on both jaws; it
had claws on the thumb and two fingers; and it had a long lizard-like tail. But
it had feathers, proving itself a true bird.
/The%20Outline%20of%20Science%20-%20Story%20of%20Evolution_files/image155c_sm.jpg "WING OF A BIRD, SHOWING THE ARRANGEMENT OF THE FEATHERS")
WING OF A BIRD, SHOWING THE ARRANGEMENT OF THE
FEATHERS
The longest feathers or primaries (PR) are borne by the two
fingers (2 and 3), and their palm-bones (CMC); the second longest or
secondaries are borne by the ulna bone (U) of the fore-arm; there is a separate
tuft (AS) on the thumb (TH).
The rarity of direct traces of life in the
oldest rocks is partly due to the fact that the primitive animals would be of
delicate build, but it must also be remembered that the ancient rocks have been
profoundly and repeatedly changed by pressure and heat, so that the traces
which did exist would be very liable to obliteration. And if it be asked what right
we have to suppose the presence of living creatures in the absence or extreme
rarity of fossils, we must point to great accumulations of limestone which
indicate the existence of calcareous algæ, and to deposits of iron which
probably indicate the activity of iron-forming Bacteria. Ancient beds of
graphite similarly suggest that green plants flourished in these ancient days.
§ 3
The Era of Ancient
Life (Palæozoic)
The Cambrian period was the time of
the establishment of the chief stocks of backboneless animals such as sponges,
jellyfishes, worms, sea-cucumbers, lamp-shells, trilobites, crustaceans, and
molluscs. There is something very eloquent in the broad fact that the peopling
of the seas had definitely begun some thirty million years ago, for Professor
H. F. Osborn points out that in the Cambrian period there was already a
colonisation of the shore of the sea, the open sea, and the deep waters.
The
Ordovician period was marked by abundant representation of the once very
successful class of Trilobites, jointed-footed, antenna-bearing, segmented
marine animals, with numerous appendages and a covering of chitin. They died
away entirely with the end of the Palæozoic era. Also very notable was the
abundance of predatory cuttlefishes, the bullies of the ancient seas. But it
was in this period that the first backboned animals made their appearance, an
epoch-making step in evolution. In other words, true fishes were evolved,
destined in the course of ages to replace the cuttlefishes (which are mere
molluscs) in dominating the seas.
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RECENT TIMES
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Human civilisation.
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{PLEISTOCENE OR GLACIAL TIME
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Last great Ice Age.
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CENOZOIC ERA
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{MIOCENE AND PLIOCENE TIMES
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Emergence of Man.
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{EOCENE AND OLIGOCENE TIMES
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Rise of higher mammals.
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{CRETACEOUS PERIOD
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Rise of primitive mammals,
flowering plants, and higher insects.
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MESOZOIC ERA
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{JURASSIC PERIOD
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Rise of birds and flying reptiles.
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{TRIASSIC PERIOD
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Rise of dinosaur reptiles.
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{PERMIAN PERIOD
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Rise of reptiles.
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{CARBONIFEROUS PERIOD
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Rise of insects.
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PALÆOZOIC ERA
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{DEVONIAN PERIOD
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First amphibians.
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{SILURIAN PERIOD
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Land animals began.
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{ORDOVICIAN PERIOD
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First fishes.
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{CAMBRIAN PERIOD
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Peopling of the sea.
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PROTEROZOIC AGES
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Many of the Backboneless stocks
began.
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ARCHÆOZOIC AGES
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Living creatures began to be upon
the earth.
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{Making of continents and
ocean-basins.
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FORMATIVE TIMES
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{Beginnings of atmosphere and
hydrosphere.
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{Cooling of the earth.
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{Establishment of the solar
system.
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In
the Silurian period in which the peopling of the seas went on apace, there
was the first known attempt at colonising the dry land. For in Silurian rocks
there are fossil scorpions, and that implies ability to breathe dry air, by
means of internal surfaces, in this case known as lungbooks. It was also
towards the end of the Silurian, when a period of great aridity set in, that
fishes appeared related to our mud-fishes or double-breathers (Dipnoi), which
have lungs as well as gills. This, again, meant utilising dry air, just as the
present-day mud-fishes do when the water disappears from the pools in hot
weather. The lung-fishes or mud-fishes of to-day are but three in number, one
in Queensland, one in South America, and one in Africa, but they are extremely
interesting "living fossils," binding the class of fishes to that of
amphibians. It is highly probable that the first invasion of the dry land
should be put to the credit of some adventurous worms, but the second great
invasion was certainly due to air-breathing Arthropods, like the pioneer
scorpion we mentioned.
/The%20Outline%20of%20Science%20-%20Story%20of%20Evolution_files/image158_sm.jpg "PICTORIAL REPRESENTATION OF THE SUCCESSIVE STRATA OF THE EARTH'S CRUST, WITH SUGGESTIONS OF CHARACTERISTIC FOSSILS")
PICTORIAL REPRESENTATION OF THE SUCCESSIVE STRATA OF
THE EARTH'S CRUST, WITH SUGGESTIONS OF CHARACTERISTIC FOSSILS
E.g. Fish and Trilobite in the Devonian (red), a large Amphibian
in the Carboniferous (blue), Reptiles in Permian (light red), the first Mammal
in the Triassic (blue), the first Bird in the Jurassic (yellow), Giant Reptiles
in the Cretaceous (white), then follow the Tertiary strata with progressive
mammals, and Quaternary at the top with man and mammoth.
The Devonian period, including that
of the Old Red Sandstone, was one of the most significant periods in the
earth's history. For it was the time of the establishment of flowering plants
upon the earth and of terrestrial backboned animals. One would like to have
been the discoverer of the Devonian foot-print of Thinopus, the first
known Amphibian foot-print, an eloquent vestige of the third great invasion of
the dry land. It was probably from a stock of Devonian lung-fishes that the
first Amphibians sprang, but it was not till the next period that they came to
their own. While they were still feeling their way, there was a remarkable
exuberance of shark-like and heavily armoured fishes in the Devonian seas.