Emerging biogeochemical views of Earth's ancient microbial worlds

Timothy W. Lyons; David A. Fike; Aubrey Zerkle

doi:10.2113/gselements.11.6.415

Emerging biogeochemical views of Earth's ancient microbial worlds

Timothy W. Lyons, David A. Fike, Aubrey Zerkle

Research output: Contribution to journal › Article › peer-review

23 Scopus citations

Abstract

Microbial processes dominate geochemical cycles at and near the Earth's surface today. Their role was even greater in the past, with microbes being the dominant life form for the first 90% of Earth's history. Most of their metabolic pathways originated billions of years ago as both causes and effects of environmental changes of the highest order, such as the first accumulation of oxygen in the oceans and atmosphere. Microbial processes leave behind diverse geochemical fingerprints that can remain intact for billions of years. These rock-bound signatures are now steering our understanding of how life coevolved with the environments on early Earth and are guiding our search for life elsewhere in the universe.

Original language	English
Pages (from-to)	415-421
Number of pages	7
Journal	Elements
Volume	11
Issue number	6
DOIs	https://doi.org/10.2113/gselements.11.6.415
State	Published - Dec 2015

Keywords

Astrobiology
Biogeochemical cycles
Biosignatures
Early Earth
Environmental change
Isotopes
Microbiology

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10.2113/gselements.11.6.415

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AB - Microbial processes dominate geochemical cycles at and near the Earth's surface today. Their role was even greater in the past, with microbes being the dominant life form for the first 90% of Earth's history. Most of their metabolic pathways originated billions of years ago as both causes and effects of environmental changes of the highest order, such as the first accumulation of oxygen in the oceans and atmosphere. Microbial processes leave behind diverse geochemical fingerprints that can remain intact for billions of years. These rock-bound signatures are now steering our understanding of how life coevolved with the environments on early Earth and are guiding our search for life elsewhere in the universe.

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KW - Isotopes

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Emerging biogeochemical views of Earth's ancient microbial worlds

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Keywords

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