Development and characterization of a low-density TiNbZrAlTa refractory high entropy alloy with enhanced compressive strength and plasticity

A new refractory high entropy alloy (RHEA) is designed by combining refractory elements Nb and Ta with Ti, Zr, and Al, resulting in a (TiNbZr)89(AlTa)11 alloy composition with a low-density of 6.0 g/cm3. The novel RHEA features a BCC matrix with B2 and Zr5Al3 nano precipitates, exhibiting a compressive yield strength of -890 MPa and specific yield strength of -148.3 MPa g-1 cm3. Remarkably, the alloy demonstrates excellent compressive plasticity of -70% at 298 K. As the temperature increases to 873 K, 1073 K, and 1273 K, the yield strength of the RHEA gradually decreases to -610 MPa, - 210 MPa, and - 60 MPa, respectively. These results indicate that this novel RHEA showcases a combination of good specific strength and plasticity. Post-compression, B2, and Zr5Al3 phases are observed. The second-phase particles dispersed throughout the grains hinder dislocation motion and contribute to the formation of sub-grain boundaries during hot compression.

Automated summary

A novel refractory high entropy alloy (RHEA) with a low-density and good specific strength and plasticity has been designed and studied. The alloy demonstrates excellent compressive plasticity and specific yield strength, showing potential for applications in high-temperature environments.