Litcius/Paper detail

Maximum strength and dislocation patterning in multi–principal element alloys

Penghui Cao

2022Science Advances105 citationsDOIOpen Access PDF

Abstract

Multi-principal element alloys (MPEAs) containing three or more components in high concentrations render a tunable chemical short-range order (SRO). Leveraging large-scale atomistic simulations, we probe the limit of Hall-Petch strengthening and deformation mechanisms in a model CrCoNi alloy and unravel chemical ordering effects. The presence of SRO appreciably increases the maximum strength and lowers the propensity for faulting and structure transformation, accompanied by intensification of planar slip and strain localization. Deformation grains exhibit notably different microstructures and dislocation patterns that prominently depend on their crystallographic orientation and the number of active slip planes. Grain of single-planar slip attains the highest volume fraction of deformation-induced structure transformation, and grain with double-slip planes develops the densest dislocation network. These results advancing the fundamental understanding of deformation mechanisms and dislocation patterning in MPEAs suggest a mechanistic strategy for tuning mechanical behavior through simultaneously tailoring grain texture and local chemical order.

Topics & Concepts

DislocationMaterials sciencePrincipal (computer security)Element (criminal law)Composite materialComputer scienceLawPolitical scienceOperating systemHigh Entropy Alloys StudiesAdditive Manufacturing Materials and ProcessesIntermetallics and Advanced Alloy Properties