Open AccessShock compression and spallation of single crystal tantalum
Author(s) -
ShengNian Luo
Publication year - 2012
Publication title -
aip conference proceedings
Language(s) - English
Resource type - Conference proceedings
SCImago Journal Rank - 0.177
H-Index - 75
eISSN - 1551-7616
pISSN - 0094-243X
DOI - 10.1063/1.3686509
Subject(s) - spallation , spall , materials science , embedded atom model , crystal twinning , shock (circulatory) , nucleation , compression (physics) , deformation (meteorology) , void (composites) , plasticity , tantalum , single crystal , composite material , anisotropy , dislocation , metallurgy , molecular dynamics , crystallography , thermodynamics , chemistry , neutron , optics , quantum mechanics , medicine , physics , computational chemistry , microstructure
We present molecular dynamics simulations of shock-induced plasticity and spall damage in single crystal Ta described by a recently developed embedded-atom-method (EAM) potential and a volumedependent qEAM potential. We use impact or Hugoniotstat simulations to investigate the Hugoniots, deformation and spallation. Both EAM and qEAM are accurate in predicting, e.g., the Hugoniots and γ - surfaces. Deformation and spall damage are anisotropic for Ta single crystals. Our preliminary results show that twinning is dominant for [100] and [110] shock loading, and dislocation, for [111]. Spallation initiates with void nucleation at defective sites from remnant compressional deformation or tensile plasticity. Spall strength decreases with increasing shock strength, while its rate dependence remains to be explored.
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