Microstructure and mechanical property of Al56-xCo24Cr20Nix eutectic high-entropy alloys with an ordered FCC/BCT phase structure

A Fe-free Al56-xCo24Cr20Nix (x = 34, 36, 38, 40, and42, denoted as Nix alloys hereafter) eutectic high-entropy alloys were designed and prepared to investigate the effect of Al and Ni content on the microstructure and mechanical property. It was found that all five alloys exhibited a typical eutectic microstructure and an ordered FCC/BCT phase structure, and the volume fraction of BCT phase reduced with an increase in Ni content. The FCC and BCT phases were enriched in Cr-Co and Al-Ni elements respectively, and the nano -scale precipitates forming in BCT phase also exhibited a BCT phase structure but enriched in Cr element. The Ni38 alloy displayed an entire eutectic microstructure with two types of eutectic lamellas, the long and straight one, and the short and curve one. The irregular lamellas resulted in an unsatisfactory tensile property in Ni38 alloy with a yield strength of 543 MPa and a fracture strain of 8.1 %. To optimize the strength-plasticity configuration, the Ni content was further fine-turned. The Ni38.5 alloy, exhibiting a regularly and fine lamellar hypereutectic microstructure with bits of primary FCC phase, was found pre-senting an improved fracture strain of 14.5 % and without any reduction in yield strength compared with Ni38 alloy. (c) 2022 Elsevier B.V. All rights reserved.

Automated summary

A series of Fe-free Al56-xCo24Cr20Nix (x = 34, 36, 38, 40, and 42) eutectic high-entropy alloys were designed and prepared to study the influence of Al and Ni content on microstructure and mechanical properties. The results revealed that all the alloys exhibited a typical eutectic microstructure and an ordered FCC/BCT phase structure. Increasing Ni content led to a reduction in the volume fraction of the BCT phase. The Ni38 alloy showed an unsatisfactory tensile property due to irregular eutectic lamellas, while the Ni38.5 alloy with a regularly and fine lamellar hypereutectic microstructure exhibited improved fracture strain without compromising yield strength.