An atomistic study connecting underlying dislocation behavior with superior mechanical properties of NiCoCr medium entropy alloy

T Banerjee and A Sharma and S Picak and M Lattemann and P Singh, MATERIALS TODAY COMMUNICATIONS, 44, 112065 (2025).

DOI: 10.1016/j.mtcomm.2025.112065

NiCoCr-based medium-entropy alloy (MEA) with a simple face-centered cubic crystal phase exhibits excellent mechanical properties, often attributed to the synergy of multiple deformation mechanisms. However, the atomistic origin of their outstanding mechanical response, including microstructural evolution and dislocation behavior under varying strain- rates and orientation, remains unclear. In this work, we employ large- scale molecular dynamics (MD) simulations to investigate the changes in deformation mechanisms along three distinct orientations (110, 111, 100) under varying strain rates (1 x108/sec, 1 x1010/sec, 1 x1012/sec) in the NiCoCr MEA. The presence of the stair-rod and the Shockley partial dislocations under uniaxial tensile strain are found to play a key role in the formation of deformation twinning and epsilon- martensite, which positively correlates with strain-rate dependent dislocation analysis. These findings further establish the role of the dislocations in controlling the superior mechanical response and excellent fracture toughness of the NiCoCr MEA. Systematic transmission- electron microscopy tests performed on the 111-oriented crystals, deformed at different strain levels, at room temperature provide clear evidence of both the extended stacking-fault and the stair rods, confirming the predicted microstructural features. This study offers key insights into the complex nucleation mechanisms of deformation twinning and epsilon-martensite, such as twinning - and transformation-induced plasticity (TWIP-TRIP), providing valuable guidelines for studying similar material classes.

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