Atomistic Simulations of the Shock and Spall Behavior of the Refractory High‑Entropy Alloy HfNbTaTiZr
ORAL
Abstract
Using molecular dynamics simulation, we study the effect of a shock wave on the refractory high-entropy alloy HfNbTaTiZr.
A single-crystalline sample, shocked along the [001] direction, is considered. The initial compression leads to only weak
dislocation activity and a bcc → hcp transformation in some regions of the sample. After the shock wave is reflected from
the free back surface of the sample, hcp transforms back to bcc, and twins are formed in the bcc phase. The sample spalls
under the high tensile pressures developing after wave reflection. In this stage, we observe dislocation activity from the
twin boundaries and inside the nanograins generated by twinning. Under the large tensile stresses, some fcc phase appears
together with disordered amorphous regions where voids nucleate and lead to spall. The fracture surfaces follow the twin
boundaries set up in the compression phase. The spall strength is similar to the one found in simulations of other bcc metals
at similar strain rates. Similar simulations for the equiatomic HfNbTaZr HEA show the same qualitative behavior, with twins
and reduced dislocation activity, but without phase transformations.
A single-crystalline sample, shocked along the [001] direction, is considered. The initial compression leads to only weak
dislocation activity and a bcc → hcp transformation in some regions of the sample. After the shock wave is reflected from
the free back surface of the sample, hcp transforms back to bcc, and twins are formed in the bcc phase. The sample spalls
under the high tensile pressures developing after wave reflection. In this stage, we observe dislocation activity from the
twin boundaries and inside the nanograins generated by twinning. Under the large tensile stresses, some fcc phase appears
together with disordered amorphous regions where voids nucleate and lead to spall. The fracture surfaces follow the twin
boundaries set up in the compression phase. The spall strength is similar to the one found in simulations of other bcc metals
at similar strain rates. Similar simulations for the equiatomic HfNbTaZr HEA show the same qualitative behavior, with twins
and reduced dislocation activity, but without phase transformations.
*Open Access funding enabled and organized by ProjektDEAL. DT and NM greatly appreciate the financial supportfrom the Simulation Science Center Clausthal / Göttingen and theGerman Research Foundation (DFG) (GU 1530/11-1, SPP 2315,and GU 1530/6-1). ORD and EMB thank support from a SIIPUNCUYO-2022-2023 grant, from PICTO-UUMM-2019-00048, andfrom PIP 2021-2023 11220200102578CO.
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Presenters
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Daniel Thürmer
- Technical University of Clausthal