Enhanced strength-ductility synergy via novel bifunctional nano-precipitates in a high-entropy alloy

High-entropy alloys (HEAs) with a single-phased face-centered-cubic structure possess excellent plasticity but generally low strength. Precipitation strengthening is one of the most promising methods to improve the strength of alloys. However, plagued by a nerve-wracking fact that strength-ductility trade-off frequently limits the improvement of alloy properties. To overcome this problem, a new Ni-35(CoFe)(55)V5Nb5 HEA with an excellent strength and ductility synergy was developed by introducing a novel bifunctional L-12-Ni3Nb nano-precipitate. This HEA exhibits a high yield strength of 855 MPa, ultimate tensile strength of 1,302 MPa and marvelous elongation of ~ 50%. First-principles calculations show that the (Ni24Co18Fe6)(3)(Nb10V4Fe2) nano-precipitate with a L-12 structure possesses lower formation energy than that with D0(22) structure. The novel nano-precipitates provide two-fold functions. On the one hand, L-12-(Ni24Co18Fe6)(3)(Nb10V4Fe2) nano-precipitates have a high anti-phase boundary energy, contributing to a significant increment in the yield strength through precipitation strengthening. More importantly, the precipitation of the precipitates lowers the stacking fault energy (SFE) of the alloy matrix, contributing to the excellent work-hardening ability and large plasticity through activating the continuous formation of SF networks and Lomer-Cottrell locks during deformation. The strategy to introduce the novel bifunctional nano-precipitates paves a new way to enhance the strength-ductility synergy of alloys.

Automated summary

A new Ni-35(CoFe)(55)V5Nb5 high-entropy alloy with a novel bifunctional L-12-Ni3Nb nano-precipitate was developed to enhance the strength and ductility synergy of the alloy, showing high yield strength, ultimate tensile strength, and remarkable elongation. The novel nano-precipitates play a dual role in improving the alloy properties through precipitation strengthening and lowering the stacking fault energy for better work-hardening ability and plasticity.