Redox state of earth's magma ocean and its venus-like early atmosphere
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Sossi, Paolo
Burnham, Antony
Badro, James
Lanzirotti, A.
Newville, Matthew
O'Neill, Hugh
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American Association for the Advancement of Science
Abstract
Exchange between a magma ocean and vapor produced Earth's earliest atmosphere. Its speciation depends on the oxygen fugacity (fO2) set by the Fe3+/Fe2+ ratio of the magma ocean at its surface. Here, we establish the relationship between fO2 and Fe3+/Fe2+ in quenched liquids of silicate Earth-like composition at 2173 K and 1 bar. Mantle-derived rocks have Fe3+/(Fe3++Fe2+) = 0.037 +- 0.005, at which the magma ocean defines an fO2 0.5 log units above the iron-wuestite buffer. At this fO2, the solubilities of H-C-N-O species in the magma ocean produce a CO-rich atmosphere. Cooling and condensation of H2O would have led to a prebiotic terrestrial atmosphere composed of CO2-N2, in proportions and at pressures akin to those observed on Venus. Present-day differences between Earth's atmosphere and those of her planetary neighbors result from Earth's heliocentric location and mass, which allowed geologically long-lived oceans, in-turn facilitating CO2 drawdown and, eventually, the development of life.
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P. A. Sossi, A. D. Burnham, J. Badro, A. Lanzirotti, M. Newville, H. S. O’Neill, Redox state of Earth’s magma ocean and its Venus-like early atmosphere. Sci. Adv.6, eabd1387 (2020).help
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Science Advances
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Open Access
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Commons Attribution NonCommercial License 4.0 (CC BY-NC)
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