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Destabilization of deep oxidized mantle drove the Great Oxidation Event

Craig O’Neill, Sonja Aulbach

2022Science Advances24 citationsDOIOpen Access PDF

Abstract

The rise of Earth’s atmospheric O 2 levels at ~2.4 Ga was driven by a shift between increasing sources and declining sinks of oxygen. Here, we compile recent evidence that the mantle shows a significant increase in oxidation state leading to the Great Oxidation Event (GOE), linked to sluggish upward mixing of a deep primordial oxidized layer. We simulate this scenario by implementing a new rheological model for this oxidized, bridgmanite-enriched viscous material and demonstrate slow mantle mixing in simulations of early Earth’s mantle. The eventual homogenization of this layer may take ~2 Ga, in line with the timing of the observed mantle redox shift, and would result in the increase in upper mantle oxidation of >1 log( f O 2 ) unit. Such a shift would alter the redox state of volcanic degassing products to more oxidized species, removing a major sink of atmospheric O 2 and allowing oxygen levels to rise at ~2.4 Ga.

Topics & Concepts

Mantle (geology)Event (particle physics)GeologyEarth scienceGeochemistryPhysicsQuantum mechanicsGeological and Geochemical AnalysisHigh-pressure geophysics and materialsearthquake and tectonic studies
Destabilization of deep oxidized mantle drove the Great Oxidation Event | Litcius