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Main Authors: Grèbol-Tomàs, P., Ibáñez-Insa, J., Trigo-Rodríguez, J. M., Peña-Asensio, E., Oliva, R., Díaz-Anichtchenko, D., Botella, P., Sánchez-Martín, J., Turnbull, R., Errandonea, D., Liang, A., Popescu, C., Sort, J.
Format: Preprint
Published: 2024
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Online Access:https://arxiv.org/abs/2412.18010
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author Grèbol-Tomàs, P.
Ibáñez-Insa, J.
Trigo-Rodríguez, J. M.
Peña-Asensio, E.
Oliva, R.
Díaz-Anichtchenko, D.
Botella, P.
Sánchez-Martín, J.
Turnbull, R.
Errandonea, D.
Liang, A.
Popescu, C.
Sort, J.
author_facet Grèbol-Tomàs, P.
Ibáñez-Insa, J.
Trigo-Rodríguez, J. M.
Peña-Asensio, E.
Oliva, R.
Díaz-Anichtchenko, D.
Botella, P.
Sánchez-Martín, J.
Turnbull, R.
Errandonea, D.
Liang, A.
Popescu, C.
Sort, J.
contents The mechanical properties of minerals in planetary materials are not only interesting from a fundamental point of view but also critical to the development of future space missions. Here we present nanoindentation experiments to evaluate the hardness and reduced elastic modulus of olivine, (Mg, Fe)2SiO4, in meteorite NWA 12008, a lunar basalt. Our experiments suggest that the olivine grains in this lunaite are softer and more elastic than their terrestrial counterparts. Also, we have performed synchrotron-based high-pressure X-ray diffraction (HP-XRD) measurements to probe the compressibility properties of this meteorite and, for comparison purposes, of three ordinary chondrites. The HP-XRD results suggest that the axial compressibility of the orthorhombic $b$ lattice parameter of olivine relative to terrestrial olivine is higher in NWA 12008 and also in the highly-shocked Chelyabinsk meteorite. The origin of the observed differences is discussed. A simple model combining the results of both our nanoindentation and HP-XRD measurements allows us to describe the contribution of macroscopic and chemical-bond related effects, both of which are necessary to reproduce the observed elastic modulus softening. Such joint analysis of the mechanical and elastic properties of meteorites and returned samples opens up a new avenue for characterizing these highly interesting materials.
format Preprint
id arxiv_https___arxiv_org_abs_2412_18010
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Mechanical softening and enhanced elasticity of lunar olivine probed via nanoindentation and high-pressure X-ray diffraction measurements
Grèbol-Tomàs, P.
Ibáñez-Insa, J.
Trigo-Rodríguez, J. M.
Peña-Asensio, E.
Oliva, R.
Díaz-Anichtchenko, D.
Botella, P.
Sánchez-Martín, J.
Turnbull, R.
Errandonea, D.
Liang, A.
Popescu, C.
Sort, J.
Earth and Planetary Astrophysics
Materials Science
The mechanical properties of minerals in planetary materials are not only interesting from a fundamental point of view but also critical to the development of future space missions. Here we present nanoindentation experiments to evaluate the hardness and reduced elastic modulus of olivine, (Mg, Fe)2SiO4, in meteorite NWA 12008, a lunar basalt. Our experiments suggest that the olivine grains in this lunaite are softer and more elastic than their terrestrial counterparts. Also, we have performed synchrotron-based high-pressure X-ray diffraction (HP-XRD) measurements to probe the compressibility properties of this meteorite and, for comparison purposes, of three ordinary chondrites. The HP-XRD results suggest that the axial compressibility of the orthorhombic $b$ lattice parameter of olivine relative to terrestrial olivine is higher in NWA 12008 and also in the highly-shocked Chelyabinsk meteorite. The origin of the observed differences is discussed. A simple model combining the results of both our nanoindentation and HP-XRD measurements allows us to describe the contribution of macroscopic and chemical-bond related effects, both of which are necessary to reproduce the observed elastic modulus softening. Such joint analysis of the mechanical and elastic properties of meteorites and returned samples opens up a new avenue for characterizing these highly interesting materials.
title Mechanical softening and enhanced elasticity of lunar olivine probed via nanoindentation and high-pressure X-ray diffraction measurements
topic Earth and Planetary Astrophysics
Materials Science
url https://arxiv.org/abs/2412.18010