The earth's history dates back more than 4.5 billion years which is divided roughly into 2 eons called the "cryptozoic[?]" [Gr. kryptos, hidden + zoo, life] and the "Phanerozic[?]" [Gr. phanerous, visible + zoo, life]. The division of these two eons is the boundary of the Precambrian and the Cambrian which occurred about 600ma (600ma means 600 million years before present, ie 600,000,000 bp).
Originally it was thought that life began with the Cambrian. Evidence suggests that during this time the earth experienced perhaps the biggest explosion of diverse life forms that ever have been on the planet, and that since that time the total number of phyla has been gradually reduced with extinction after extinction (ref. Stephen Jay Gould: Wonderful life - the Story of the Cambrian and the Burgess Shale). Some influential researchers, including Briton Simon Conway Morris[?], an expert in the Burgess Shales, dispute the assertion that there were significantly more phyla at this time, suggesting that a number of creatures assigned to new phyla (particularly Hallucigenia) were actually arthropods or onychophores.
Later work established that life evolved rather early in the history of the planet, perhaps as long as 4 billion years ago. Recent research suggests that life appeared on Earth just as soon as the planet cooled sufficiently for it to do so, and indeed may have arisen and been destroyed multiple times by planetismal impacts before the planet stabilized. This possibility has prompted some scientists to suggest that life is common in the universe, since it appeared so quickly here.
Some of the mile stones that mark the history of the planet are as follows:
4,000ma - earliest biogenic carbon
3,700ma - oldest rocks
3,500ma - oldest stromatolites
3,500ma - first evidence of sex [ref. Origins of Sex : Three Billion Years of Genetic Recombination, Lynn Margulis and Dorion Sagan, Yale University Press, Hartford, Connecticut, 1990, trade paperback, ISBN 0300046197 ]
3,450ma - earliest bacteria
3,800ma - banded iron formations (with reduced iron)
3,000ma - earliest precambrian ice ages [need ref]
[?] - Chuos Tillites of South-West Africa
[?] - Sturtian Tillites of the Finders Range, South-central Australia
3,000ma - earliest photosynthetic bacteria
2,700ma - oldest chemical evidence of complex cells
2,300ma - first green algae (eukaryotes)
2,000ma - free oxygen in the atmosphere
2,000ma to 1600ma - Gowganda tillites in the Canadian shield
1,700ma - end of the banded iron formations and red beds become abundant (non-reducing atmosphere)
700ma - first metazoans
600ma - first skeletons
600ma to present - phanerozic eon
[history of the phanerozoic goes in here]
100ma - development of the angiosperms (flowering plants)
2ma to present - modern world and man's appearance on earth
[whole history of man goes in here about 1/2000th of the time scale]
0.015ma - end of the last ice age
0.0007ma - warming trend of the middle ages
0.0003ma - end of the mini ice age
0.00015ma to present - industrialized world and the introduction of man made greenhouse gases.
[we need a chart showing all this - horizontal format I think will be best - with zoom capability]
The earliest atmosphere of the earth was probably blown off early in the history of the planet. These gases were later replaced by an atmosphere derived from outgassing from the earth. It is in this way that the oceans and the present atmosphere came to be.
Free oxygen did not exist until about 1,700ma and this can be seen with the development of the red beds and the end of the banded iron formations. This signifies a shift from a reducing atmosphere to a non-reducing atmosphere.
The early atmosphere and hydrosphere (up until about 2,000ma) were devoid of free Oxygen. Gradually early photosynthesis managed to convert the abundant CO2 releasing O2.
The very early atmosphere of the earth contained mostly carbon dioxide (CO2) : about 80%. This gradually dropped to about 20% by 3,500ma. This coincides with the development of the first bacteria about 3,500ma.
By the time of the development of photosynthesis (2,700ma), CO2 levels in the atmosphere were in the range of 15%. During the period from about 2,700ma to about 2,000ma photosythesis dropped the CO2 concentrations from about 15% to about 8%. By about 2,000ma free O2 was beginning to accumulate. This gradual reduction in CO2 levels continued to about 600ma at which point CO2 levels were below 1% and O2 levels had risen to more than 15%.
600ma corresponds to the end of the Precambrian and the beginning of the Cambrian, the end of the cryptozoic and the beginning of the phanerozic, and the beginning of oxygen breathing life.
The climate of the late cryptozoic was typically cold with glaciation spreading over much of the earth. At this time the continents were bunched up in a super continent called Rodina. Massive deposits of Tillites are found and anomalous isotopic signatures are found which are consistent with the idea that the earth at this time was a massive snowball.
[we need a map of Rodina here showing the extent of the glaciation and where the continents were - Australia was near the equator then and Stuartin Tillites were deposited - can we get a picture of the geological section from the Flinders Range?]
As the cryptozoic eon drew to a close the earth started to warm up. By the dawn of the Cambrian and the phanerozoic eon, Planet earth was experiencing average global temperatures of about +22C. 100's of millions of years of ice were replaced with the balmy tropical seas of the Cambrian Period during which life exploded at a rate never seen before nor after. [ref. Stephen Jay Gould - wonderful life, the Story of the Burgess Shale].
[to be continued]
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