Amorphization and Plasticity of Olivine During Low-Temperature Micropillar Deformation Experiments

Kelly Kranjc; Arashdeep S. Thind; Albina Y. Borisevich; Rohan Mishra; Katharine M. Flores; Philip Skemer

doi:10.1029/2019JB019242

Amorphization and Plasticity of Olivine During Low-Temperature Micropillar Deformation Experiments

Kelly Kranjc, Arashdeep S. Thind, Albina Y. Borisevich, Rohan Mishra, Katharine M. Flores, Philip Skemer

electron Microscopy and Microanalysis

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

6 Scopus citations

Abstract

Experimentally quantifying the viscoplastic rheology of olivine at the high stresses and low temperatures of the shallow lithosphere is challenging due to olivine's propensity to deform by brittle mechanisms at these conditions. In this study, we use microscale uniaxial compression tests to investigate the rheology of an olivine single crystal at room pressure and temperature. Pillars with nominal diameters of 1.25 μm were prepared using a focused ion beam milling technique and were subjected to sustained axial stresses of several gigapascal. The majority of the pillars failed after dwell times ranging from several seconds to a few hours. However, several pillars exhibited clear evidence of plastic deformation without failure after 4–8 hr under load. The corresponding creep strain rates are estimated to be on the order of 10⁻⁶ to 10⁻⁷ s⁻¹. The uniaxial stresses required to achieve this deformation (4.1–4.4 GPa) are in excellent agreement with complementary data obtained using nanoindentation techniques. Scanning transmission electron microscopy observations indicate that deformation occurred along amorphous shear bands within the deformed pillars. Electron energy loss spectroscopy measurements revealed that the bands are enriched in Fe and depleted in Mg. We propose that inhomogeneities in the cation distribution in olivine concentrate stress and promote the amorphization of the Fe-rich regions. The time dependence of catastrophic failure events suggests that the amorphous bands must grow to some critical length scale to generate an unstable defect, such as a shear crack.

Original language	English
Article number	e2019JB019242
Journal	Journal of Geophysical Research: Solid Earth
Volume	125
Issue number	5
DOIs	https://doi.org/10.1029/2019JB019242
State	Published - May 1 2020

Funding

The sample tested here is identified in the manuscript (Table 1) using the IGSN registration number provided by SESAR. Additional data are archived using the Open Scholarship Data Repository (doi:10.7936/dwtx-rc52) This work was supported by the National Science Foundation under Grant No. EAR-17-26165. The authors also acknowledge financial support from Washington University in St. Louis and the Institute of Materials Science and Engineering (IMSE) for the use of the SEM and TEM and for staff assistance. TEM foils were prepared with financial support of the University of Michigan College of Engineering and technical support from the Michigan Center for Materials Characterization. STEM work performed at Oak Ridge National Laboratory was supported by the U.S. Department of Energy, Office of Science, Basic Energy Sciences Materials Science and Engineering Division (BES-MSED). The authors thank the Washington University Center for Cellular Imaging (WUCCI) for their assistance in fabricating the FIB micropillars, Paul Carpenter for his assistance with the EPMA, and Mike Sly for his contributions. Two anonymous reviewers are thanked for their constructive comments. The sample tested here is identified in the manuscript (Table 1 ) using the IGSN registration number provided by SESAR. Additional data are archived using the Open Scholarship Data Repository (doi: 10.7936/dwtx‐rc52 ) This work was supported by the National Science Foundation under Grant No. EAR‐17‐26165. The authors also acknowledge financial support from Washington University in St. Louis and the Institute of Materials Science and Engineering (IMSE) for the use of the SEM and TEM and for staff assistance. TEM foils were prepared with financial support of the University of Michigan College of Engineering and technical support from the Michigan Center for Materials Characterization. STEM work performed at Oak Ridge National Laboratory was supported by the U.S. Department of Energy, Office of Science, Basic Energy Sciences Materials Science and Engineering Division (BES‐MSED). The authors thank the Washington University Center for Cellular Imaging (WUCCI) for their assistance in fabricating the FIB micropillars, Paul Carpenter for his assistance with the EPMA, and Mike Sly for his contributions. Two anonymous reviewers are thanked for their constructive comments.

Keywords

3902 creep and deformation
3904 defects
8033 rheology: mantle

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10.1029/2019JB019242

Cite this

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title = "Amorphization and Plasticity of Olivine During Low-Temperature Micropillar Deformation Experiments",

abstract = "Experimentally quantifying the viscoplastic rheology of olivine at the high stresses and low temperatures of the shallow lithosphere is challenging due to olivine's propensity to deform by brittle mechanisms at these conditions. In this study, we use microscale uniaxial compression tests to investigate the rheology of an olivine single crystal at room pressure and temperature. Pillars with nominal diameters of 1.25 μm were prepared using a focused ion beam milling technique and were subjected to sustained axial stresses of several gigapascal. The majority of the pillars failed after dwell times ranging from several seconds to a few hours. However, several pillars exhibited clear evidence of plastic deformation without failure after 4–8 hr under load. The corresponding creep strain rates are estimated to be on the order of 10−6 to 10−7 s−1. The uniaxial stresses required to achieve this deformation (4.1–4.4 GPa) are in excellent agreement with complementary data obtained using nanoindentation techniques. Scanning transmission electron microscopy observations indicate that deformation occurred along amorphous shear bands within the deformed pillars. Electron energy loss spectroscopy measurements revealed that the bands are enriched in Fe and depleted in Mg. We propose that inhomogeneities in the cation distribution in olivine concentrate stress and promote the amorphization of the Fe-rich regions. The time dependence of catastrophic failure events suggests that the amorphous bands must grow to some critical length scale to generate an unstable defect, such as a shear crack.",

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AU - Mishra, Rohan

AU - Flores, Katharine M.

AU - Skemer, Philip

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N2 - Experimentally quantifying the viscoplastic rheology of olivine at the high stresses and low temperatures of the shallow lithosphere is challenging due to olivine's propensity to deform by brittle mechanisms at these conditions. In this study, we use microscale uniaxial compression tests to investigate the rheology of an olivine single crystal at room pressure and temperature. Pillars with nominal diameters of 1.25 μm were prepared using a focused ion beam milling technique and were subjected to sustained axial stresses of several gigapascal. The majority of the pillars failed after dwell times ranging from several seconds to a few hours. However, several pillars exhibited clear evidence of plastic deformation without failure after 4–8 hr under load. The corresponding creep strain rates are estimated to be on the order of 10−6 to 10−7 s−1. The uniaxial stresses required to achieve this deformation (4.1–4.4 GPa) are in excellent agreement with complementary data obtained using nanoindentation techniques. Scanning transmission electron microscopy observations indicate that deformation occurred along amorphous shear bands within the deformed pillars. Electron energy loss spectroscopy measurements revealed that the bands are enriched in Fe and depleted in Mg. We propose that inhomogeneities in the cation distribution in olivine concentrate stress and promote the amorphization of the Fe-rich regions. The time dependence of catastrophic failure events suggests that the amorphous bands must grow to some critical length scale to generate an unstable defect, such as a shear crack.

AB - Experimentally quantifying the viscoplastic rheology of olivine at the high stresses and low temperatures of the shallow lithosphere is challenging due to olivine's propensity to deform by brittle mechanisms at these conditions. In this study, we use microscale uniaxial compression tests to investigate the rheology of an olivine single crystal at room pressure and temperature. Pillars with nominal diameters of 1.25 μm were prepared using a focused ion beam milling technique and were subjected to sustained axial stresses of several gigapascal. The majority of the pillars failed after dwell times ranging from several seconds to a few hours. However, several pillars exhibited clear evidence of plastic deformation without failure after 4–8 hr under load. The corresponding creep strain rates are estimated to be on the order of 10−6 to 10−7 s−1. The uniaxial stresses required to achieve this deformation (4.1–4.4 GPa) are in excellent agreement with complementary data obtained using nanoindentation techniques. Scanning transmission electron microscopy observations indicate that deformation occurred along amorphous shear bands within the deformed pillars. Electron energy loss spectroscopy measurements revealed that the bands are enriched in Fe and depleted in Mg. We propose that inhomogeneities in the cation distribution in olivine concentrate stress and promote the amorphization of the Fe-rich regions. The time dependence of catastrophic failure events suggests that the amorphous bands must grow to some critical length scale to generate an unstable defect, such as a shear crack.

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Amorphization and Plasticity of Olivine During Low-Temperature Micropillar Deformation Experiments

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