Atomistic simulations of shock induced microstructural evolution and spallation in single crystal nickel

S. G. Srinivasan; M. I. Baskes; G. J. Wagner

doi:10.1063/1.2423084

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Atomistic simulations of shock induced microstructural evolution and spallation in single crystal nickel

Journal article

Peer reviewed

Atomistic simulations of shock induced microstructural evolution and spallation in single crystal nickel

S. G. Srinivasan, M. I. Baskes and G. J. Wagner

Journal of applied physics, Vol.101(4), p.043504

02/15/2007

DOI: https://doi.org/10.1063/1.2423084

Abstract and subjects

Physical Sciences

Physics

Physics, Applied

Science & Technology

Spallation in single crystalline nickel was studied using molecular dynamics simulations. The shock waves-incident waves, the waves reflected from sample free surfaces, and interference between reflected waves-create and destroy many microstructural features. These features, though unimportant in determining the spall strength, control the spall nucleation site. Spall occurs by cavitation at a grain boundary junction in cold, defective, tensile regions of the sample. Atomistic calculations and experiments, though separated by six orders of magnitude in strain rates, follow a universal strain rate behavior.

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Title: Atomistic simulations of shock induced microstructural evolution and spallation in single crystal nickel
Authors/Creators - name: S. G. Srinivasan
M. I. Baskes
G. J. Wagner
Publication Details: Journal of applied physics, Vol.101(4), p.043504
Publisher: Amer Inst Physics
Number of pages: 7
Language: English
Resource Type: Journal article
DOI: https://doi.org/10.1063/1.2423084
Publication ISSN: 0021-8979; 1089-7550