Iron Partitioning between Ferropericlase and Bridgmanite in the Earth's Lower Mantle
Shenzhen Xu, Jung-Fu Lin, Dane Morgan

TL;DR
This study develops an integrated thermodynamic model revealing a stratified lower mantle with distinct iron chemistry and spin states, explaining seismic and chemical heterogeneity observed in recent tomography images.
Contribution
It introduces a comprehensive thermodynamic model of iron and aluminum chemistry that explains the stratification and seismic inhomogeneity of Earth's lower mantle.
Findings
Identifies a transition at ~1600 km depth driven by ferropericlase spin transition.
Predicts a 3-4% decrease in bulk sound velocity in the mid-lower mantle.
Shows increased density (~1%) toward the lowermost mantle due to chemical stratification.
Abstract
Earth's lower mantle is generally believed to be seismically and chemically homogeneous because most of the key seismic parameters can be explained using a simplified mineralogical model at expected press-temperature conditions. However, recent high-resolution tomographic images have revealed seismic and chemical stratification in the middle-to-lower parts of the lower mantle. Thus far, the mechanism for the compositional stratification and seismic inhomogeneity, especially their relationship with the speciation of iron in the lower mantle, remains poorly understood. We have built a complete and integrated thermodynamic model of iron and aluminum chemistry for lower mantle conditions, and from this model has emerged a stratified picture of the valence, spin and composition profile in the lower mantle. Within this picture the lower mantle has an upper region with Fe3+ enriched…
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