Deformation and strength of mantle relevant garnets: Implications for the subduction of basaltic-rich crust

Cara E. Vennari; Feng Lin; Martin Kunz; Masaki Akaogi; Lowell Miyagi; Quentin Williams

doi:10.2138/am-2021-7587

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Deformation and strength of mantle relevant garnets: Implications for the subduction of basaltic-rich crust

Cara E. Vennari , Feng Lin , Martin Kunz , Masaki Akaogi , Lowell Miyagi und Quentin Williams

Veröffentlicht/Copyright: 3. Juli 2021

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Aus der Zeitschrift American Mineralogist Band 106 Heft 7

Abstract

Garnet is an important mineral phase in the upper mantle as it is both a key component in bulk mantle rocks, and a primary phase at high pressure within subducted basalt. Here, we focus on the strength of garnet and the texture that develops within garnet during accommodation of differential deformational strain. We use X‑ray diffraction in a radial geometry to analyze texture development in situ in three garnet compositions under pressure at 300 K: a natural garnet (Prp₆₀Alm₃₇) to 30 GPa, and two synthetic majorite-bearing compositions (Prp₅₉Maj₄₁ and Prp₄₂Maj₅₈) to 44 GPa. All three garnets develop a modest (100) texture at elevated pressure under axial compression. Elasto-visco-plastic self-consistent (EVPSC) modeling suggests that two slip systems are active in the three garnet compositions at all pressures studied: {110}<111> and {001}<110>. We determine a flow strength of ~5 GPa at pressures between 10 to 15 GPa for all three garnets; these values are higher than previously reported yield strengths measured on natural and majoritic garnets. Strengths calculated using the experimental lattice strain differ from the strength generated from those calculated using EVPSC. Prp₆₇Alm₃₃, Prp₅₉Maj₄₁, and Prp₄₂Maj₅₈ are of comparable strength to each other at room temperature, which indicates that majorite substitution does not greatly affect the strength of garnets. Additionally, all three garnets are of similar strength as lower mantle phases such as bridgmanite and ferropericlase, suggesting that garnet may not be notably stronger than the surrounding lower mantle/deep upper mantle phases at the base of the upper mantle.

Keywords: High-pressure experiment; diamond-anvil cell; garnet; texture; strength; radial X‑ray diffraction

† Present address: Department of Aerospace Engineering, Iowa State University, Iowa 50011, U.S.A.

Funding statement: We thank the following funding sources: U.S. NSF (EAR-1620423, EAR-1654687, EAR PF-1855336, EAR-2017294). Additional support from the U.S. Department of Energy, National Nuclear Security Administration, through the Chicago/DOE Alliance Center (DE-NA0003975). This research used resources of the Advanced Light Source (beamline 12.2.2) at Lawrence Berkeley National Laboratory, which is DOE Office of Science User facility under Contract No. DE-AC02-05CH11231. This research was partially supported by COMPRES, the Consortium for Materials Properties Research in Earth Sciences under NSF Cooperative Agreement EAR 1606856.

Acknowledgments

We thank Jinyuan Yan for help in preparation of the gaskets and Sam Couper for useful conversations.

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Received: 2020-05-04

Accepted: 2020-09-16

Published Online: 2021-07-03

Published in Print: 2021-07-27

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https://doi.org/10.2138/am-2021-7587

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High-pressure experiment; diamond-anvil cell; garnet; texture; strength; radial X‑ray diffraction