Atomistic study of inverse size effect induced by interfacial plasticity in pearlitic multi-principal element alloy
C Yang and QS Xia and CH Yin and DP Hua, RARE METALS, 43, 3341-3355 (2024).
DOI: 10.1007/s12598-024-02664-2
Owing to the fine nano-laminated structure, the pearlitic multi- principal element alloy (PMPEA) exhibits excellent mechanical and tribological properties. However, the incomplete understanding of the size effect of its lamella thickness and the unclear understanding of the plasticity-interface interaction mechanism limit further optimization of PMPEAs. In this study, the FeCoNi/Ni3Ti interface- mediated plastic deformation behavior in PMPEA and the variation of mechanical and tribological properties with lamella thickness within the nanoscale range using molecular dynamics (MD) simulation were explored. The results indicate that the mechanical and tribological properties of the PMPEA with lamella thicknesses below 10 nm have a significant inverse size effect, i.e., the smaller the lamella thickness, the weaker the properties. This is because the plastic carrier-interface interaction mechanism changes from a strengthening mechanism that hinders dislocations to a weakening mechanism that promotes dislocations with the decreases in the lamella thickness, and the weakening effect becomes more pronounced as the lamella thickness decreases and the number of interfaces increases. In particular, the deformation behavior of Ni3Ti lamellae changes from crystal-like to amorphous-like with decreasing lamella. Moreover, in the sample with larger lamella thickness, the occurrence of hierarchical slips in the body-centered cubic (BCC) phase due to the multi-principal elements effect can better alleviate the stress concentration caused by the dislocation accumulation at the interface, so that the phase interface exhibits outstanding load-bearing effects. And the dislocation pattern in BCC phase shows a firm high-density cell, which makes the substrate exhibit a stable tribological response.
Return to Publications page