Crystal plasticity finite element simulation of lattice rotation and x-ray diffraction during laser shock compression of tantalum

Journal article

We present a crystal plasticity model tailored for high-pressure, high-strain-rate conditions that uses a multiscale treatment of dislocation-based slip kinetics. We use this model to analyze the pronounced plasticity-induced lattice rotations observed in shock-compressed polycrystalline tantalum via in situ x-ray diffraction. By making direct comparisons between experimentally measured and simulated texture evolution, we can explain how the details of the underlying slip kinetics control the degree of lattice rotation that ensues. Specifically, we show that only the highly nonlinear kinetics caused by dislocation nucleation can explain the magnitude of the rotation observed under shock compression. We demonstrate a good fit between our crystal plasticity model and x-ray diffraction data and exploit the data to quantify the dislocation nucleation rates that are otherwise poorly constrained by experiment in the dynamic compression regime.

Authors: Avraam, P; McGonegle, D; Heighway, PG; Wehrenberg, CE; Floyd, E

• Publication status: Published
• Peer review status: Peer reviewed
• Publisher: American Physical Society
• Journal: Physical Review Materials
• Volume: 7
• Issue: 11
• Article number: 113608
• Publication date: 2023-11-27
• Acceptance date: 2023-06-06
• DOI: 10.1103/physrevmaterials.7.113608
• EISSN: 2475-9953
• ISSN: 2476-0455
• Language: English
• Keywords: compressive strength; mechanical deformation; shock waves; microstructure; FFR; pressure effects; lattice dynamics; plasticity; mechanical and acoustical properties