Nanoindentation characteristics of nanocrystalline tungsten via atomistic simulation

YQ Hu and JF Xu and L Su and XM Liu and YH Zhang and SH Ding and R Wang and R Xia, PHILOSOPHICAL MAGAZINE, 103, 749-767 (2023).

DOI: 10.1080/14786435.2023.2173328

Molecular dynamics simulations are performed to explore nanoindentation characteristics of tungsten, and the influences of grain size, indenter velocity, indenter size, and temperature are discussed. The results illustrate that the hardness reduces as the grain size (5.00 similar to 24.62 nm) decreases. There is no phase change observed during the whole deformation process. For monocrystalline W, the dislocation nucleation and propagation dominate the deformation mechanisms. Differently, the primary deformation mode of nanocrystalline W is the grain split and motion of GBs. Dislocations primarily nucleate below the contact surface of the indenter and substrate and then glide in the grain core. The monocrystalline W has better pattern-forming ability than nanocrystalline. Besides, the pattern-forming ability of nanocrystalline W is negatively correlated with the average grain size (5.00 similar to 24.62 nm). The von Mises stress is mainly concentrated in the interface between the indenter and substrate, the dislocation area for monocrystalline, and grain boundaries for nanocrystalline. The indentation force and hardness are positively correlated with indenter radius size (30 similar to 80 angstrom), negatively correlated with temperature (10 similar to 1500 K), and insensitive to the indenter velocity when velocity is lower than 3.0 angstrom /ps (300 m/s).

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