Enhanced mechanical performance of gradient‐structured CoCrFeMnNi high‐entropy alloys induced by industrial shot‐blasting
Mingzhi Zhang, Kun Zhang, Kaikai Song, Xiao-Yu Zou, Weidong Song, Ke-Feng Li, Lina Hu, Zequn Zhang, J. Eckert
Abstract
Abstract In this study, CoCrFeMnNi high‐entropy alloys (HEAs) with a surface gradient nanostructure were produced using industrial shot blasting, which improved their mechanical properties compared to the untreated alloy. The severely plastically deformed (SPD) surface layer had a multi‐scale hierarchical structure with a high density of stacking faults, deformation nanotwins, and amorphous domains. The depth of the SPD layer steadily increased as the shot‐blasting time increased. The differences in the microhardness and tensile strength before and after shot‐blasting demonstrated the significant effect of the SPD layer on the mechanical performance. The microhardness of the homogenized HEA was ~ 5 GPa. In comparison, the maximum microhardness of the specimens after 20 min of shot blasting was ~ 8.0 GPa at the surface. The yield strength also improved by 178%, and a large ductility of ~ 36% was retained. Additional nanograin boundary, stacking fault, and twin strengthening within the gradient‐nanostructured surface layer caused the strength to increase. During tensile deformation, strain concentration began at the surface of the specimen and gradually spread to the interior. Thus, the gradient‐nanostructured surface layer with improved strain hardening can prevent early necking and ensure steady plastic deformation so that high toughness is achieved.