Snowball Earth Musings

A lot of this theoretical thinking is premature at best, but we have seen snowball earth and other models enthusiastically picked up on over the years.

A look at the various moons of Jupiter, Saturn and Uranus promises no simple answer. Any early model of earth’s atmosphere must add in methane at least and a lot of it, all of which with carbon dioxide would have established a gaseous atmosphere with maximum greenhouse heat retention while sponging up the oxygen been produced by emerging life.

Yet I have seen little mention of methane in the literature. Since I am unaware of any Precambrian oil deposition, or coal deposition, this seems a bit curious because it begs the question of where might it be hiding besides the atmosphere?

The oceans produced oxygen and grabbed carbon from somewhere to sequester in the sediments. It is a pretty good bet that methane was a big atmospheric factor up to the point that life was able to leave the ocean and its final decline may in fact been the initiating event.

My point is simply that there is an incredible amount of carbon tied up in the sediments that has made it there solely as a result of biological processes. It was tied up in the form of CO2 and Methane at the beginning just like every other planet we are able to look at.

Unless I am missing something, most of it was accumulated post Precambrian when life was already established on land.

It may have been snowball earth, but the liquid ocean certainly existed and was slowly growing and brewing up the necessary changes that set the stage for life to transition onto land. It may have been associated with Deep Ocean and volcanism to begin with, because the early snowball earth must have comprised both ice and frozen methane as in the arctic permafrost. And as in Antarctica, regions would even have had frozen CO2.

In the end, life had to strip carbon and produce water from the mostly frozen gas mix from the very beginning and this process dominated until the methane and CO2 was almost fully reduced. This makes exploring similar planets very interesting.

Modern day scourge helped ancient Earth escape a deathly deep freeze

The planet's present day greenhouse scourge, carbon dioxide, may have played a vital role in helping ancient Earth to escape from complete glaciation, say scientists in a paper published online today.

In their review for Nature Geoscience, UK scientists claim that the Earth never froze over completely during the Cryogenian Period, about 840 to 635 million years ago.

This is contrary to the Snowball Earth hypothesis, which envisages a fully frozen Earth that was locked in ice for many millions of years as a result of a runaway chain reaction that caused the planet to cool.

What enabled the Earth to escape from a complete freeze is not certain, but the UK scientists in their review point to recent research carried out at the University of Toronto. This speculates that the advancing ice was stalled by the interaction of the physical climate system and the carbon cycle of the ocean, with carbon dioxide playing a key role in insulating the planet.

The Toronto scientists say that as Earth's temperatures cooled, oxygen was drawn into the ocean, where it oxidized organic matter, releasing the greenhouse gas carbon dioxide into the atmosphere.

The review's lead author, Professor Phillip Allen, from Imperial College London's Department of Earth Science and Engineering, says that something must have kept the planet's equatorial oceans from freezing over. He adds:

"In the climate change game, carbon dioxide can be both saint and sinner. These days we are so concerned about global warming and the harm that carbon dioxide is doing to our planet. However, approximately 600 million years ago, this greenhouse gas probably saved ancient Earth and its basic life forms from an icy extinction."

Professor Allen, whose previous research has found evidence demonstrating hot and cold cycles in the Cryogenian period, says a plethora of papers has been published and much debate has been devoted to the Snowball Earth theory since it was originally proposed. He says:

"Sedimentary rocks deposited during these cold intervals indicate that dynamic glaciers and ice streams continued to deliver large amounts of sediment to open oceans. This evidence contradicts the Snowball Earth theory, which suggests the oceans were frozen over. Yet, many scientists still believe Snowball Earth to be correct."

Professor Allen hopes his review in Nature will prompt climate modellers to realign their thinking about the Cryogenian period and review their models to reflect a warmer Earth during this time. He adds:

"There is so much about Earth's ancient past that we don't know enough about. So it is really important that climate modellers get their targets right. They need to build into their calculations a warmer planet, with open oceans, despite lower levels of solar radiation at this time. Otherwise, climate models about the Earth's distant past are aiming for a target that never existed."

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