Microbial roles equivalent to geological agents of high temperature and pressure in deep Earth

Microbes not only show sensitive responses to environmental changes but also play important roles in geochemical and geophysical systems. It is well known that microbes have caused major changes in surface environments and biogeochemical cycles through Earth history. Microbial processes can also ind...

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Veröffentlicht in:	Science China. Earth sciences 2016-11, Vol.59 (11), p.2098-2104
Hauptverfasser:	Xie, ShuCheng, Liu, Deng, Qiu, Xuan, Huang, XianYu, Algeo, Thomas J.
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Sprache:	eng
Schlagworte:	Biogeochemical cycles Biotransformation Chemical reactions Dolomite Earth Earth and Environmental Science Earth Sciences Environmental changes Geology High temperature Illite Pressure Progress
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creator	Xie, ShuCheng Liu, Deng Qiu, Xuan Huang, XianYu Algeo, Thomas J.
description	Microbes not only show sensitive responses to environmental changes but also play important roles in geochemical and geophysical systems. It is well known that microbes have caused major changes in surface environments and biogeochemical cycles through Earth history. Microbial processes can also induce the synthesis of certain minerals under Earth-surface conditions that previously were believed to form only under high temperatures and pressures in the deep Earth. For example, microbes can promote the conversion of smectite to illite, synthesis of authigenic plagioclase, precipitation of dolomite, and biotransformation of geolipids. These effects of microbes are due to their large surface/volume ratios, enzyme production, and abundant functional groups. Microbial catalyzation of chemical reactions proceeds through reaction-specific enzymes, a decrease in Gibbs＇ s free energy, and/or break through the dynamics reaction thresholds via their metabolisms and physiology. Microbes can lower the surface free energy of mineral nuclei via biophysical adsorption due to their large surface/volume ratios and abundant functional groups. The mineral precipitation and transformation processes induced by microbes are functionally equivalent to geological processes operating at high temperatures and pressures in the deep Earth, suggesting that microbial processes can serve as analogs to deep abiotic processes that are difficult to observe.
doi_str_mv	10.1007/s11430-015-5442-1
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subjects	Biogeochemical cycles Biotransformation Chemical reactions Dolomite Earth Earth and Environmental Science Earth Sciences Environmental changes Geology High temperature Illite Pressure Progress
title	Microbial roles equivalent to geological agents of high temperature and pressure in deep Earth
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