Spatial description of dislocation nucleation in the shock response of single-crystal aluminum

A Archer and K Campbell and DE Spearot, JOURNAL OF APPLIED PHYSICS, 137, 085102 (2025).

DOI: 10.1063/5.0239019

Nonequilibrium molecular dynamics simulations of shock loaded single- crystal Al in the < 100 >, < 110 >, < 111 >, and < 123 > orientations are conducted to study elastic and plastic shockwave formation and details associated with dislocation activity. A computer vision-based approach is implemented to capture the presence of dislocations and describe their spatial characteristics in the zone of nucleation behind the propagating shockwave. The methodology developed relies on the sequences of images extracted during shock loading that show dislocation activity within a cross section of the sample. Results reveal that the spacing between activated slip systems is orientation dependent and exhibits a modest reduction for the < 100 > and < 111 > orientations as shock pressure increases. Comparisons are made to existing theoretical models. Such relationships between shock pressure and dislocation activity, extracted from molecular dynamics simulations, can be used to inform higher length scale simulations or modeling of dislocation-based plasticity during shock.

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