Using simultaneous x-ray diffraction and velocity interferometry to determine material strength in shock-compressed diamond

Macdonald, M. J.; Mcbride, E. E.; Galtier, E.; Gauthier, M.; Granados, E.; Kraus, Dominik; Krygier, A.; Levitan, A. L.; Mackinnon, A. J.; Nam, I.; Schumaker, W.; Sun, P.; Driel, T. B. van; Vorberger, Jan; Zhou, X.; Drake, R. P.; Glenzer, S. H.; Fletcher, L. B.

doi:10.1063/5.0013085

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Using simultaneous x-ray diffraction and velocity interferometry to determine material strength in shock-compressed diamond

Macdonald, M. J.; Mcbride, E. E.; Galtier, E.; Gauthier, M.; Granados, E.; Kraus, D.; Krygier, A.; Levitan, A. L.; Mackinnon, A. J.; Nam, I.; Schumaker, W.; Sun, P.; van Driel, T. B.; Vorberger, J.; Zhou, X.; Drake, R. P.; Glenzer, S. H.; Fletcher, L. B.

Abstract

We determine the strength of laser shock-compressed polycrystalline diamond at stresses above the Hugoniot elastic limit using a novel technique combining x-ray diffraction from the Linac Coherent Light Source with velocity interferometry. X-ray diffraction is used to measure lattice strains and velocity interferometry is used to infer shock and particle velocities. These measurements, combined with density-dependent elastic constants calculated using density functional theory, enable determination of material strength above the Hugoniot elastic limit. Our results indicate that diamond retains approximately 20 GPa of strength at longitudinal stresses of 150–300 GPa under shock compression.

Keywords: diffraction; diamond; strength; high pressure; shock; Hugoniot

Applied Physics Letters 116(2020), 234104
DOI: 10.1063/5.0013085
Cited 11 times in Scopus

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