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Hall–Petch and grain growth kinetics of the low stacking fault energy TRIP Cr40Co40Ni20 multi-principal element alloy

Gustavo Bertoli, Lucas Barcelos Otani, Amy J. Clarke, Cláudio Shyinti Kiminami, Francisco Gil Coury

2021Applied Physics Letters22 citationsDOI

Abstract

The Cr40Co40Ni20 multi-principal element alloy (MPEA) displays a single-phase face centered cubic initial structure, which partially transforms to hexagonal close packed (HCP) phase by transformation-induced plasticity (TRIP) during straining, as evidenced by nanometric HCP lamellae that provide enhanced mechanical properties. This MPEA also exhibits significant yield strength—grain size dependence, given by the high Hall–Petch coefficients (k = 667 MPa/μm−0.5 and σ0 = 299 MPa). The high activation energy for grain growth (QG = 533 kJ/mol) leads to refined grain structures after conventional heat treatments. These features, combined with the large solid solution strengthening of Cr-rich Cr-Co-Ni MPEAs, grant the Cr40Co40Ni20 alloy a great combination of strength and ductility under tension. Finally, an empirical equation is proposed to describe the stacking fault energy (SFE) of Cr-Co-Ni alloys, contributing to the prediction of the acting deformation mechanisms. Such findings highlight the potential of compositional tuning to enhance multiple strength and deformation mechanisms in the Cr-Co-Ni system.

Topics & Concepts

Materials scienceStacking-fault energyAlloyGrain boundary strengtheningGrain sizeDuctility (Earth science)Grain boundaryStacking faultDeformation (meteorology)PlasticityMetallurgyGrain growthPhase (matter)Strengthening mechanisms of materialsDislocationCondensed matter physicsCrystallographyComposite materialMicrostructureCreepChemistryPhysicsOrganic chemistryHigh Entropy Alloys StudiesAdditive Manufacturing Materials and ProcessesHigh-Temperature Coating Behaviors
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