Daniel J. Frost scite author profile

The composition of Earth’s atmosphere depends on the redox state of the mantle, which became more oxidizing at some stage after Earth’s core started to form. Through high-pressure experiments, we found that Fe2+ in a deep magma ocean would disproportionate to Fe3+ plus metallic iron at high pressures. The separation of this metallic iron to the core raised the oxidation state of the upper mantle, changing the chemistry of degassing volatiles that formed the atmosphere to more oxidized species. Additionally, the resulting gradient in redox state of the magma ocean allowed dissolved CO2 from the atmosphere to precipitate as diamond at depth. This explains Earth’s carbon-rich interior and suggests that redox evolution during accretion was an important variable in determining the composition of the terrestrial atmosphere.

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Highly siderophile elements were stripped from Earth’s mantle by iron sulfide segregation

Rubie

Laurenz

Jacobson

et al. 2016

Science

111

106

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Highly siderophile elements (HSEs) are strongly depleted in the bulk silicate Earth (BSE) but are present in near-chondritic relative abundances. The conventional explanation is that the HSEs were stripped from the mantle by the segregation of metal during core formation but were added back in near-chondritic proportions by late accretion, after core formation had ceased. Here we show that metal-silicate equilibration and segregation during Earth's core formation actually increased HSE mantle concentrations because HSE partition coefficients are relatively low at the high pressures of core formation within Earth. The pervasive exsolution and segregation of iron sulfide liquid from silicate liquid (the "Hadean matte") stripped magma oceans of HSEs during cooling and crystallization, before late accretion, and resulted in slightly suprachondritic palladium/iridium and ruthenium/iridium ratios.

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In situ structure determination of the high-pressure phase of Fe₃O₄

Fei

Frost

Mao

et al. 1999

American Mineralogist

127

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Daniel J. Frost

Deep magma ocean formation set the oxidation state of Earth’s mantle

Highly siderophile elements were stripped from Earth’s mantle by iron sulfide segregation

In situ structure determination of the high-pressure phase of Fe₃O₄

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Daniel J. Frost

Deep magma ocean formation set the oxidation state of Earth’s mantle

Highly siderophile elements were stripped from Earth’s mantle by iron sulfide segregation

In situ structure determination of the high-pressure phase of Fe3O4

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In situ structure determination of the high-pressure phase of Fe₃O₄