Abstract
The effect of vacancies on dynamic response and spallation in single-crystal magnesium (Mg) is investigated by nonequilibrium molecular dynamics simulations. The initial vacancy concentration (Cv) ranges from 0% to 2.0%, and the shock loading is applied along [0001] and [10–10] directions. The simulation results show that the effects of vacancy defects are strongly dependent on the shock directions. For shock along the [0001] direction, vacancy defects have a negligible effect on compression-induced plasticity, but play a role in increasing spall damage. In contrast, for shock along the [10–10] orientation, vacancy defects not only provide the nucleation sites for compression-induced plasticity, which mainly involves crystallographic reorientation, phase transition, and stacking faults, but also significantly reduce spall damage. The degree of spall damage is probably determined by a competitive mechanism between energy absorption and stress attenuation induced by plastic deformation. Void evolution during spallation is mainly based on the emission mechanism of dislocations. The {11–22} <11–23> pyramidal dislocation facilitates the nucleation of void in the [0001] shock, as well as the {1–100} <11–20> prismatic dislocation in the [10–10] shock. We also investigated the variation of spall strength between perfect and defective Mg at different shock velocities. The relevant results can provide a reference for future investigations on spall damage.
Highlights
Spallation is an important subject in dynamic damage research, which can be observed in the local tensile stress region caused by the interaction of the unloading compression wave and rarefaction wave formed from the free surface of the target
Agarwal and Dongare [14] investigated the effects of loading direction, impact pressure, and initial temperature on spallation of single-crystal magnesium with Molecular dynamics (MD) simulations, and found that the spall strength decreased with the increase in impact strength and initial temperature
A compressive shock wave was produced in the sample that travels towards the rear surface
Summary
Publisher’s Note: MDPI stays neutral with regard to jurisdictional claims in published maps and institutional affiliations. Luo et al [10] studied spall damage of single-crystal Cu under square and Taylor shock wave loading using MD simulations. Agarwal and Dongare [14] investigated the effects of loading direction, impact pressure, and initial temperature on spallation of single-crystal magnesium with MD simulations, and found that the spall strength decreased with the increase in impact strength and initial temperature. Chen et al [13] studied the effect of grain boundaries (GBs) on spall behavior in the metal Ta by MD simulations They demonstrated the correlation between GB structure, GB plasticity mechanism, and the resulting spall strength. The main purpose is to analyze the effect of vacancy concentration on spallation of single-crystal magnesium under different loading directions, with an initial concentration ranging from 0% to 2.0%.
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