Nonisentropic Release of a Shocked Solid

Abstract

We present molecular dynamics (MD) simulations of shock and release in micron-scale tantalum crystals that exhibit post-breakout temperatures far exceeding those expected under the standard assumption of isentropic release. We show via an energy-budget analysis that this is due to plastic-work heating from material strength that largely counters thermoelastic cooling. The simulations are corroborated by experiments where the release temperatures of laser-shocked tantalum foils are deduced from their thermal strains via in situ x-ray diffraction, and are found to be close to those behind the shock.

Metadata

Authors/Creators:	Heighway, Patrick Sliwa, M. McGonegle, David Wehrenberg, C. E. Bolme, C. Eggert, J.H. Higginbotham, Andrew https://orcid.org/0000-0001-5211-9933 Lazicki, A. E. Lee, Hae Ja Nagler, Bob Park, Hye-Sook Rudd, R. E. Smith, R. F. Suggit, Mathew Swift, D. C. Tavella, F. Remington, Bruce A. Wark, J S
Copyright, Publisher and Additional Information:	This is an author-produced version of the published paper. Uploaded with permission of the publisher/copyright holder. Further copying may not be permitted; contact the publisher for details
Dates:	Accepted: 9 October 2019 Published: 13 December 2019
Institution:	The University of York
Academic Units:	The University of York > Faculty of Sciences (York) > Physics (York)
Depositing User:	Pure (York)
Date Deposited:	12 Dec 2019 10:40
Last Modified:	06 Dec 2023 13:23
Published Version:	https://doi.org/10.1103/PhysRevLett.123.245501
Status:	Published
Refereed:	Yes
Identification Number:	https://doi.org/10.1103/PhysRevLett.123.245501

Download

Accepted Version

Filename: Isentropic_heating_preprint.pdf

Description: Non-isentropic Release of a Shocked Solid

CLICK TO DOWNLOAD

CORE (COnnecting REpositories)

Nonisentropic Release of a Shocked Solid

Abstract

Metadata

Download

Accepted Version

Export

Statistics