Redox States of Initial Atmospheres Outgassed on Rocky Planets and Planetesimals

The Earth and other rocky planets and planetesimals in the solar system formed through the mixing of materials from various radial locations in the solar nebula. This primordial material likely had a range of oxidation states as well as bulk compositions and volatile abundances. We investigate the o...

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Veröffentlicht in:	The Astrophysical journal 2017-07, Vol.843 (2), p.120
Hauptverfasser:	Schaefer, Laura, Fegley, Bruce
Format:	Artikel
Sprache:	eng
Schlagworte:	ABUNDANCE APPROXIMATIONS Astrophysics ASTROPHYSICS, COSMOLOGY AND ASTRONOMY Binary mixtures COSMIC GASES DEGASSING FRACTIONATION Fugacity Gas composition Gases Lava METALS METEORITES meteorites, meteors, meteoroids METEOROIDS MIXING Outgassing OXIDATION OXYGEN Planet formation Planetary atmospheres PLANETS planets and satellites: atmospheres planets and satellites: terrestrial planets SATELLITE ATMOSPHERES SATELLITES SOLAR NEBULA SOLAR SYSTEM Solar system evolution Terrestrial planets Trace elements Trace metals
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description	The Earth and other rocky planets and planetesimals in the solar system formed through the mixing of materials from various radial locations in the solar nebula. This primordial material likely had a range of oxidation states as well as bulk compositions and volatile abundances. We investigate the oxygen fugacity produced by the outgassing of mixtures of solid meteoritic material, which approximate the primitive nebular materials. We find that the gas composition and oxygen fugacity of binary and ternary mixtures of meteoritic materials vary depending on the proportion of reduced versus oxidized material, and also find that mixtures using differentiated materials do not show the same oxygen fugacity trends as those using similarly reduced but undifferentiated materials. We also find that simply mixing the gases produced by individual meteoritic materials together does not correctly reproduce the gas composition or oxygen fugacity of the binary and ternary mixtures. We provide tabulated fits for the oxygen fugacities of all of the individual materials and binary mixtures that we investigate. These values may be useful in planetary formation models, models of volatile transport on planetesimals or meteorite parent bodies, or models of trace element partitioning during metal-silicate fractionation.
doi_str_mv	10.3847/1538-4357/aa784f
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This primordial material likely had a range of oxidation states as well as bulk compositions and volatile abundances. We investigate the oxygen fugacity produced by the outgassing of mixtures of solid meteoritic material, which approximate the primitive nebular materials. We find that the gas composition and oxygen fugacity of binary and ternary mixtures of meteoritic materials vary depending on the proportion of reduced versus oxidized material, and also find that mixtures using differentiated materials do not show the same oxygen fugacity trends as those using similarly reduced but undifferentiated materials. We also find that simply mixing the gases produced by individual meteoritic materials together does not correctly reproduce the gas composition or oxygen fugacity of the binary and ternary mixtures. We provide tabulated fits for the oxygen fugacities of all of the individual materials and binary mixtures that we investigate. 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J</addtitle><description>The Earth and other rocky planets and planetesimals in the solar system formed through the mixing of materials from various radial locations in the solar nebula. This primordial material likely had a range of oxidation states as well as bulk compositions and volatile abundances. We investigate the oxygen fugacity produced by the outgassing of mixtures of solid meteoritic material, which approximate the primitive nebular materials. We find that the gas composition and oxygen fugacity of binary and ternary mixtures of meteoritic materials vary depending on the proportion of reduced versus oxidized material, and also find that mixtures using differentiated materials do not show the same oxygen fugacity trends as those using similarly reduced but undifferentiated materials. We also find that simply mixing the gases produced by individual meteoritic materials together does not correctly reproduce the gas composition or oxygen fugacity of the binary and ternary mixtures. We provide tabulated fits for the oxygen fugacities of all of the individual materials and binary mixtures that we investigate. 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subjects	ABUNDANCE APPROXIMATIONS Astrophysics ASTROPHYSICS, COSMOLOGY AND ASTRONOMY Binary mixtures COSMIC GASES DEGASSING FRACTIONATION Fugacity Gas composition Gases Lava METALS METEORITES meteorites, meteors, meteoroids METEOROIDS MIXING Outgassing OXIDATION OXYGEN Planet formation Planetary atmospheres PLANETS planets and satellites: atmospheres planets and satellites: terrestrial planets SATELLITE ATMOSPHERES SATELLITES SOLAR NEBULA SOLAR SYSTEM Solar system evolution Terrestrial planets Trace elements Trace metals
title	Redox States of Initial Atmospheres Outgassed on Rocky Planets and Planetesimals
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