Abstract
Twinning in fcc High Entropy Alloys (HEAs) has been implicated as a possible mechanism for hardening that enables enhanced ductility. Here, a theory for the twinning stress is developed analogous to recent theories for yield stress. Specifically, the stress to move a twin dislocation, i.e an fcc partial dislocation moving along a pre-existing twin boundary, through a random multicomponent alloy is determined. A reduced elasticity theory is then introduced in which atoms interact with the twin dislocation pressure field and the twin boundary. The theory is applied to NiCoCr using results from both interatomic potentials and elasticity theory. Results are also used to predict the increased stress for the motion of (i) a single partial dislocation leaving a trailing stacking fault and (ii) adjacent partial dislocations involved in twin nucleation. Increased strength is predicted for all processes involved in the nucleation and growth of fcc twins. Comparison to single-crystal experiments at room temperature then suggests that twinning is controlled by twin nucleation, with reasonable quantitative agreement. When solute/fault interactions are neglected, the theory shows that twinning and lattice flow stresses are related. The theory also provides insight into how other dilute solute additions could suppress twinning, as found experimentally.
Highlights
Various fcc High Entropy Alloys (HEAs) have shown excellent mechanical properties, especially a combination of high strength and high ductility [1,2,3,4,5]
The stress required to move a twin dislocation in a random alloy has been studied using solute strengthening theory and applied to the NiCoCr medium entropy alloy
The twin growth stress is lower than experiments, indicating that twinning is controlled by nucleation
Summary
Various fcc High Entropy Alloys (HEAs) have shown excellent mechanical properties, especially a combination of high strength and high ductility [1,2,3,4,5]. We develop the theory for the stress τt,growth for motion of a partial dislocation along the pre-existing twin boundary (Fig. 1c). We predict that the twin partial is strengthened significantly in the random alloy due mainly to the elastic interactions of the twin dislocation with the solutes.
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