Elastic shear anisotropy of ferropericlase in earth's lower mantle

Hauke Marquardt; Sergio Speziale; Hans J. Reichmann; Daniel J. Frost; Frank R. Schilling; Edward Garnero

doi:10.1126/science.1169365

Elastic shear anisotropy of ferropericlase in earth's lower mantle

Hauke Marquardt, Sergio Speziale, Hans J. Reichmann, Daniel J. Frost, Frank R. Schilling, Edward Garnero

Earth and Space Exploration, School of (SESE)

Research output: Contribution to journal › Article › peer-review

123 Scopus citations

Abstract

Seismic shear anisotropy in the lowermost mantle most likely results from elastic shear anisotropy and lattice preferred orientation of its constituent minerals, including perovskite, post-perovskite, and ferropericlase. Measurements of the elastic shear anisotropy of single-crystal (Mg _0.9Fe_0.1)O up to 69 gigapascals (GPa) show that it increased considerably across the pressure-induced spin transition of iron between 40 and 60 GPa. Increasing iron content further enhances the anisotropy. This leads to at least 50% stronger elastic shear anisotropy of (Mg,Fe)O in the lowermost mantle compared to MgO, which is typically used in geodynamic modeling. Our results imply that ferropericlase is the dominant cause of seismic shear anisotropy in the lower mantle.

Original language	English (US)
Pages (from-to)	224-226
Number of pages	3
Journal	Science
Volume	324
Issue number	5924
DOIs	https://doi.org/10.1126/science.1169365
State	Published - Apr 10 2009

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title = "Elastic shear anisotropy of ferropericlase in earth's lower mantle",

abstract = "Seismic shear anisotropy in the lowermost mantle most likely results from elastic shear anisotropy and lattice preferred orientation of its constituent minerals, including perovskite, post-perovskite, and ferropericlase. Measurements of the elastic shear anisotropy of single-crystal (Mg 0.9Fe0.1)O up to 69 gigapascals (GPa) show that it increased considerably across the pressure-induced spin transition of iron between 40 and 60 GPa. Increasing iron content further enhances the anisotropy. This leads to at least 50% stronger elastic shear anisotropy of (Mg,Fe)O in the lowermost mantle compared to MgO, which is typically used in geodynamic modeling. Our results imply that ferropericlase is the dominant cause of seismic shear anisotropy in the lower mantle.",

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AU - Marquardt, Hauke

AU - Speziale, Sergio

AU - Reichmann, Hans J.

AU - Frost, Daniel J.

AU - Schilling, Frank R.

AU - Garnero, Edward

PY - 2009/4/10

Y1 - 2009/4/10

N2 - Seismic shear anisotropy in the lowermost mantle most likely results from elastic shear anisotropy and lattice preferred orientation of its constituent minerals, including perovskite, post-perovskite, and ferropericlase. Measurements of the elastic shear anisotropy of single-crystal (Mg 0.9Fe0.1)O up to 69 gigapascals (GPa) show that it increased considerably across the pressure-induced spin transition of iron between 40 and 60 GPa. Increasing iron content further enhances the anisotropy. This leads to at least 50% stronger elastic shear anisotropy of (Mg,Fe)O in the lowermost mantle compared to MgO, which is typically used in geodynamic modeling. Our results imply that ferropericlase is the dominant cause of seismic shear anisotropy in the lower mantle.

AB - Seismic shear anisotropy in the lowermost mantle most likely results from elastic shear anisotropy and lattice preferred orientation of its constituent minerals, including perovskite, post-perovskite, and ferropericlase. Measurements of the elastic shear anisotropy of single-crystal (Mg 0.9Fe0.1)O up to 69 gigapascals (GPa) show that it increased considerably across the pressure-induced spin transition of iron between 40 and 60 GPa. Increasing iron content further enhances the anisotropy. This leads to at least 50% stronger elastic shear anisotropy of (Mg,Fe)O in the lowermost mantle compared to MgO, which is typically used in geodynamic modeling. Our results imply that ferropericlase is the dominant cause of seismic shear anisotropy in the lower mantle.

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Elastic shear anisotropy of ferropericlase in earth's lower mantle

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