Correlating dislocation mobility with local lattice distortion in refractory multi-principal element alloys

Multi-principal element alloys (MPEAs) exhibit different degrees of intrinsic lattice distortion, which varies with constituent species. Using atomistic simulations, here we found the mobilities of both edge and screw disloca-tions are dependent on lattice distortion in body-centered-cubic (BCC) MPEAs. Lattice distortion influences not only the activation of kink nucleation and propagation governing screw dislocation motion, but also the strength of local pinning for edge dislocations. As a consequence, the disparity between the velocities of screw and edge dislocations decreases with increasing lattice distortion. We further demonstrate that lattice distortion can be taken as an indicator to correlate with the reported brittleness of BCC MPEAs. This implies that maximizing lattice distortion could be a plausible strategy to improve the ductility for brittle BCC MPEAs.

Automated summary

This study found that lattice distortion affects the mobility of dislocations in body-centered-cubic multi-principal element alloys. Lattice distortion influences the activation of kink nucleation and propagation for screw dislocation motion, as well as the strength of local pinning for edge dislocations. The lattice distortion can be used as an indicator to correlate with the reported brittleness of these alloys.