Snowball Earth:The Cryogenian Period: The Equator Under Ice
Published: December 18, 2010, 12:00 am
Updated: May 7, 2012, 6:55 pm
This article has been reviewed by the following Topic Editor:
David Hassenzahl PhD
About 0.73 Ga, Earth underwent severe glaciations that eliminated much of life. The Cryogenian (Greek; ice + birth) period was initiated by several conditions. [1] The breakup of the supercontinent Rodinia exposed organic matter to anaerobic respiration, creating an atmosphere in which the major greenhouse gas was methane (CH4). Atmospheric CH4, in contrast with CO2, reacts with O2 and is not buffered by a massive ocean reservoir; therefore, atmospheric CH4 levels decreased rapidly once continental movements diminished and less organic matter was exposed. As CH4 declined, Earth cooled. Cooler temperatures inhibited biological production of CH4, accelerating the cooling. Ice appeared on the land masses near the equator, increasing the reflectance of solar energy (a phenomenon called albedo) and decreasing the solar energy retained at Earth’s surface. Temperatures sank until even some equatorial oceans were covered with ice. [2]
Recovery from these cold conditions depended on the buildup of atmospheric CO2 levels through volcanic emissions of CO2 and low-temperature inhibition of processes that deplete atmospheric CO2, namely, silicate rock weathering and photosynthesis. Atmospheric CO2 concentrations reached as high as 1.2% before the ice began to crack, exposing bare ground and open water, decreasing albedo, and creating a cascade of events that warmed the planet. [3]
This is an excerpt from the book Global Climate Change: Convergence of Disciplines by Dr. Arnold J. Bloom and taken from UCVerse of the University of California.
©2010 Sinauer Associates and UC Regents
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Citation
Arnold J Bloom (Lead Author);David Hassenzahl PhD (Topic Editor) "The Cryogenian Period: The Equator Under Ice". In: Encyclopedia of Earth. Eds. Cutler J. Cleveland (Washington, D.C.: Environmental Information Coalition, National Council for Science and the Environment). [First published in the Encyclopedia of Earth December 18, 2010; Last revised Date May 7, 2012; Retrieved May 19, 2013 <http://www.eoearth.org/article/The_Cryogenian_Period:_The_Equator_Under_Ice?topic=54287>
The Author
Arnold J. Bloom became a botanist through a circuitous route. Upon receiving an undergraduate degree in Physics from Yale University, he spent several years developing computer models of the spread of air pollution over cities in the USA and Germany. He received a Ph.D. in Biological Sciences from Stanford University, where he also completed a two-semester course in Environmental Legislation at the Law School. He conducted postdoctoral research on the temperature responses of plants at the ... (Full Bio)
About 0.73 Ga, Earth underwent severe glaciations that eliminated much of life. The Cryogenian (Greek; ice + birth) period was initiated by several conditions. [1] The breakup of the supercontinent Rodinia exposed organic matter to anaerobic respiration, creating an atmosphere in which the major greenhouse gas was methane (CH4). Atmospheric CH4, in contrast with CO2, reacts with O2 and is not buffered by a massive ocean reservoir; therefore, atmospheric CH4 levels decreased rapidly once continental movements diminished and less organic matter was exposed. As CH4 declined, Earth cooled. Cooler temperatures inhibited biological production of CH4, accelerating the cooling. Ice appeared on the land masses near the equator, increasing the reflectance of solar energy (a phenomenon called albedo) and decreasing the solar energy retained at Earth’s surface. Temperatures sank until even some equatorial oceans were covered with ice. [2]
Recovery from these cold conditions depended on the buildup of atmospheric CO2 levels through volcanic emissions of CO2 and low-temperature inhibition of processes that deplete atmospheric CO2, namely, silicate rock weathering and photosynthesis. Atmospheric CO2 concentrations reached as high as 1.2% before the ice began to crack, exposing bare ground and open water, decreasing albedo, and creating a cascade of events that warmed the planet. [3]
This is an excerpt from the book Global Climate Change: Convergence of Disciplines by Dr. Arnold J. Bloom and taken from UCVerse of the University of California.
©2010 Sinauer Associates and UC Regents
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