Litcius/Paper detail

Design metastability in high-entropy alloys by tailoring unstable fault energies

Xin Wang, Rafael Rodríguez De Vecchis, Chenyang Li, Hanlei Zhang, Xiaobing Hu, Soumya Sridar, Yuankang Wang, Wei Chen, Wei Xiong

2022Science Advances56 citationsDOIOpen Access PDF

Abstract

Metastable alloys with transformation-/twinning-induced plasticity (TRIP/TWIP) can overcome the strength-ductility trade-off in structural materials. Originated from the development of traditional alloys, the intrinsic stacking fault energy (ISFE) has been applied to tailor TRIP/TWIP in high-entropy alloys (HEAs) but with limited quantitative success. Here, we demonstrate a strategy for designing metastable HEAs and validate its effectiveness by discovering seven alloys with experimentally observed metastability for TRIP/TWIP. We propose unstable fault energies as the more effective design metric and attribute the deformation mechanism of metastable face-centered cubic alloys to unstable martensite fault energy (UMFE)/unstable twin fault energy (UTFE) rather than ISFE. Among the studied HEAs and steels, the traditional ISFE criterion fails in more than half of the cases, while the UMFE/UTFE criterion accurately predicts the deformation mechanisms in all cases. The UMFE/UTFE criterion provides an effective paradigm for developing metastable alloys with TRIP/TWIP for an enhanced strength-ductility synergy.

Topics & Concepts

TwipStacking-fault energyMaterials scienceMetastabilityDuctility (Earth science)High entropy alloysCrystal twinningDeformation (meteorology)Diffusionless transformationStacking faultMartensiteDislocationMetallurgyAlloyComposite materialMicrostructurePhysicsQuantum mechanicsCreepHigh Entropy Alloys StudiesHigh-Temperature Coating BehaviorsAdditive Manufacturing Materials and Processes