Designing structures with combined gradients of grain size and precipitation in high entropy alloys for simultaneous improvement of strength and ductility

Suppressing the early strain localization at the nanostructured topmost layer is crucial for achieving better tensile ductility in the gradient structure. Thus, structures with combined gradient distributions along the depth for both grain size and volume fraction of precipitates were designed and introduced in a high entropy alloy by surface mechanical attrition treatment and aging. Yield strength and uniform elongation were observed to be simultaneously improved in the structures with combined gradients as compared to the corresponding structures with only grain size gradient. More severe strain gradients and higher density of geometrically necessary dislocations were observed to be produced at various domain boundaries in the structures with combined gradients, resulting in stronger hetero-deformation-induced (HDI) extra hardening for better tensile properties. Shearing and bowing hardening mechanisms were observed for L1( 2) and B2 precipitates, respectively. Higher volume fractions of B2 and L1( 2) phases at the topmost layer induce stronger precipitation hardening, which compensates the diminished strain hardening due to the reduced grain size at the topmost layer for better tensile ductility in the structures with combined gradients. The observed higher yield strength in the structures with combined gradients have been discussed based on mechanisms of dislocation strengthening, precipitation strengthening and HDI strengthening. (C)& nbsp;2022 Acta Materialia Inc. Published by Elsevier Ltd. All rights reserved.& nbsp;

Automated summary

Suppressing early strain localization at the nanostructured topmost layer is crucial for better tensile ductility in gradient structures. By introducing combined gradients in both grain size and volume fraction of precipitates, the alloy exhibits improved yield strength and uniform elongation. Higher strain gradients and more geometrically necessary dislocations at various domain boundaries contribute to stronger hetero-deformation-induced extra hardening. The observed higher yield strength is attributed to mechanisms of dislocation strengthening, precipitation strengthening, and HDI strengthening.