1. Oxidation state of the lower mantle: In situ observations of the iron electronic configuration in bridgmanite at extreme conditions
- Author
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Kupenko, I., McCammon, C., Sinmyo, Ryosuke, Cerantola, V., Potapkin, V., Chumakov, A. I., Kantor, A., Rueffer, R., Dubrovinsky, L., Kupenko, I, Mccammon, C, Sinmyo, R, Cerantola, V, Potapkin, V, Chumakov, A, Kantor, A, Ruffer, R, and Dubrovinsky, L
- Subjects
Laser heating ,Silicate perovskite ,Bridgmanite ,Analytical chemistry ,Mineralogy ,Perovskite ,Synchrotron ,Lower mantle ,law.invention ,High pressure ,Geophysics ,Space and Planetary Science ,Geochemistry and Petrology ,Spin crossover ,law ,Oxidation state ,Mössbauer spectroscopy ,Earth and Planetary Sciences (miscellaneous) ,Electron configuration ,Geology ,Earth (classical element) ,Iron spin state ,Perovskite (structure) - Abstract
We have investigated the electronic configuration of iron in Fe-, Al-containing magnesium silicate perovskite, i.e., bridgmanite, the main component of the lower mantle, at conditions of the deep Earth's interior using the energy domain Synchrotron Mossbauer Source technique. We show that the high ferric iron content observed previously in quenched samples is preserved at high temperatures and high pressures. Our data are consistent with high-spin to intermediate-spin (HS-IS) crossover in Fe2+ at high pressures and ambient temperature. We see no evidence of spin crossover in Fe3+ occupying the A-position of bridgmanite. On laser heating at pressures above ∼40 GPa we observe a new doublet with relative area below 5% which is assigned to Fe3+ in the octahedral (B-site) position in bridgmanite. We conclude that at lower mantle conditions Fe3+ remains predominantly in the HS state, while Fe2+ occurs solely in the IS state.
- Published
- 2015
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