# Strengthening in multi-principal element alloys with   local-chemical-order roughened dislocation pathways

**Authors:** Qing-Jie Li, Howard Sheng, Evan Ma

arXiv: 1904.07681 · 2019-09-11

## TL;DR

This paper reveals how local chemical ordering in high-entropy alloys influences dislocation pathways and enhances mechanical strength by increasing energy landscape ruggedness and activation barriers.

## Contribution

It demonstrates that local chemical order varies with processing and significantly affects dislocation behavior and strength in high-entropy alloys, a novel insight into their structural properties.

## Key findings

- Local chemical ordering varies with processing conditions.
- LCO increases energy landscape ruggedness and activation barriers.
- Enhanced strength via nanoscale segment detrapping mechanism.

## Abstract

High-entropy alloys (HEAs) were presumed to have a configurational entropy as high as that of an ideally mixed solid solution (SS) of multiple elements in near-equal proportions. However, enthalpic interactions inevitably render such chemically disordered SSs rare and metastable, except at very high temperatures. Here we highlight a structural feature that sets these concentrated SSs apart from traditional solvent-solute ones: the HEAs possess a wide variety of (local) chemical ordering (LCO). Our atomistic simulations employing an empirical interatomic potential for NiCoCr reveal that the LCO of the multi-principal-element SS changes conspicuously with alloy processing conditions, producing a wide range of generalized planar fault energy in terms of both its sample-average and spatial variation. We further demonstrate that the LCO heightens the ruggedness of the energy landscape and raises activation barriers governing dislocation activities. This not only influences the selection of dislocation pathways in slip, faulting, twinning, and martensitic transformation, but also increases the lattice friction to dislocation motion via a new mechanism of nanoscale segment detrapping that elevates the mechanical strength. All these open a vast playground not accessible to ground-state SSs or intermetallics, offering rich opportunities to tune properties.

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Source: https://tomesphere.com/paper/1904.07681