Cryogenic mechanical behavior of a TRIP-assisted dual-phase high-entropy alloy

The recently developed dual-phase (DP) non-equiatomic Fe50Mn30Co10Cr10 (at.%) high-entropy alloy (HEA) showed much higher strength and ductility compared to the single-phase equiatomic Fe20Mn20Ni20Co20Cr20 (at.%) HEA at room temperature. Herein we probe the cryogenic mechanical properties of the non-equiatomic DP-HEA with different grain sizes and compare with the equiatomic single-phase HEA. Our results show that the cryogenic ultimate tensile strengths of the coarse-grained (similar to 200 mu m) and fine-grained (similar to 4 mu m) DP-HEAs reach up to 1,133 and 1,342 MPa, respectively, which are significantly higher than that of the equiatomic single-phase HEAs with similar grain sizes. Furthermore, the fine-grained DP-HEA shows substantial improvement in both strength and ductility compared to the coarse-grained counterparts at cryogenic temperatures. Microstructural analysis reveals that the enhanced mechanical properties of the DP-HEA at cryogenic temperatures are attributed to a more extensive displacive transformation from the face-centered cubic (FCC) matrix into the hexagonal close-packed (HCP) phase compared to that at room temperature. Specifically, the HCP phase fraction in tensile tested fine-grained DP-HEAs increases from similar to 39% to similar to 79% with decreasing temperature from 298 to 77 K. The enhanced transformation behavior is enabled by the reduced stacking fault energy of the material with the decrease of deformation temperatures. The resulting outstanding combination of strength and ductility further suggests that the DP-HEAs are promising candidates as structural materials for cryogenic applications.

Automated summary

The dual-phase non-equiatomic high-entropy alloy exhibits higher strength and ductility at cryogenic temperatures compared to equiatomic single-phase HEA, with fine-grained structure showing significant advantages over coarse-grained structure due to more extensive displacive transformation. The enhanced transformation behavior is attributed to the reduced stacking fault energy of the material at lower deformation temperatures.