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Biology

What is the History of the Earth's Atmosphere?

Michael Anissimov
By
Updated May 21, 2024
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Earth has had three atmospheres, each different in chemical composition. The first of Earth's atmospheres, formed when the planet was still very young, was primarily hydrogen and helium. This atmosphere is about 4.57 billion years old, and was short-lived – heat from the molten crust and solar wind dissipated this layer. Hydrogen and helium are not heavy enough to make up a stable atmosphere unless the planet is very massive – these elements are more likely to gain escape velocity during random thermal fluctuations. This is part of the reason why hydrogen and helium are very rare in Earth's atmosphere today.

Around 4.4 billion years ago, crust solidified, and numerous volcanoes formed, ejecting steam, carbon dioxide, and ammonia into the skies. Over time, the density of these volcanic gases became sufficient to form a second Earth's atmosphere, primarily of carbon dioxide and water vapor. Some nitrogen was present, but barely any free oxygen. This is similar to Venus’ present atmosphere, which is 96.5% carbon dioxide and 3.5% nitrogen. Earth’s atmosphere at this point had something else in common with Venus – it was about 100 times denser than it is today. The pressure at the surface would have been similar to the pressure under 1 km (0.62 mi) of water.

The Earth’s atmosphere slowly began to rarify as the carbon dioxide was dissolved in the oceans and precipitated out as carbonates. This coated much of the Earth in a layer of carbon, and set the stage for early life.

By 3.5 billion years ago, life had emerged, in the form of archaea. About 2.7 billion years ago they were joined by microbes called cyanobacteria. Cyanobacteria were the first oxygen-producing phototropic organisms, and slowly began to suck in carbon dioxide from the atmosphere and release oxygen. It took a long time for the cyanobacteria to really get started, but between 2.7 and 2.2 billion years, during the early Paleoproterozoic, these microbes converted the Earth’s atmosphere from an anoxic (oxygen-lacking) atmosphere into an oxic (oxygen-containing) state. This is called the Great Oxidation or, more commonly the Oxygen Catastrophe.

The oxidation event is sometimes considered a catastrophe because, to most life forms alive at the time, oxygen was toxic. Therefore the Oxygen Catastrophe was one of the first major mass extinctions. However, as a benefit, we got another one of Earth’s atmospheres, the one we need to survive today.

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Michael Anissimov
By Michael Anissimov
Michael Anissimov is a dedicated All The Science contributor and brings his expertise in paleontology, physics, biology, astronomy, chemistry, and futurism to his articles. An avid blogger, Michael is deeply passionate about stem cell research, regenerative medicine, and life extension therapies. His professional experience includes work with the Methuselah Foundation, Singularity Institute for Artificial Intelligence, and Lifeboat Foundation, further showcasing his commitment to scientific advancement.
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Discussion Comments
By anon320465 — On Feb 18, 2013

Why did nitrogen become the most dominant gas in the atmosphere?

By anon301278 — On Nov 03, 2012

What do you mean by 'crust solidified'?

By anon274954 — On Jun 14, 2012

O.K. I think I understand, and really good explanation, by the way. What's changed to make oxygen levels increase and carbon dioxide only a minor component in the earth's atmosphere today?

By anon169649 — On Apr 22, 2011

Where did all the sulphur go? Sulphur is still being released by volcanoes. It is quickly oxidized to sulphate and rains own as acid rain. It will then react with carbonate rocks forming insoluble calcium sulphate and releasing carbon dioxide.

By anon148519 — On Feb 01, 2011

A fair explanation. I am guessing that the Nitrogen is the remnants of the broken down methane and NOx type compounds from the volcanic atmosphere.

However, another question could be most volcanoes emit huge amounts of sulfur gases, SO2, SO3 H2SO4, etc. Where did the sulphur gases go? Was the earth full of sulphur-utilizing organisms?

By anon98562 — On Jul 23, 2010

It appears to be the optimum amount required for fertilizer, for automatic nitrogen fixing into the soil by lightning, amounting to tons per acre worldwide.

By anon37958 — On Jul 22, 2009

Great explanation, but why did nitrogen become the most dominant gas in the 3rd atmosphere?

Michael Anissimov
Michael Anissimov
Michael Anissimov is a dedicated All The Science contributor and brings his expertise in paleontology, physics, biology...
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