Microstructure and mechanical properties of lightweight AlxCrNbTiV(x=0.2, 0.5, 0.8) refractory high entropy alloys

A novel lightweight refractory high entropy alloys AlxCrNbTiV (x = 0.2, 0.5 and 0.8, in terms of molar ratios) are prepared by vacuum arc melting. In the as cast condition, the alloys have BCC phase with significant dendrite structure, with a low density of 5.82-6.38 g /cm(3) and hardness increase from 462 HV0.2 to 549 HV0.2 with the solid solution strengthening effect by adding Al. Due to simultaneous dislocation motion and development of kink bands, Al0.2CrNbTiV exhibits good combination of strength and ductility at room temperature, enabling deformation in compression to epsilon > 50%, with yield strength of 1570 MPa, and attractive specific yield strength of 246 MPa & BULL;cm(3)/g. And Al0.5CrNbTiV and Al0.8CrNbTiV shows typical brittle feature. Cr2Nb-type C14 Laves phase precipitated with the compression temperature increase to 1000 C. EBSD analysis shows discontinuous dynamic recrystallization (DDRX) and continuous dynamic recrystallization (CDRX) are activated together in the hot compression process, and result in softening and a substantial increase in ductility of all the alloys. Furthermore, the theoretical yield stress of AlxCrNbTiV is calculated through estimating the solid solution strength effect attributed to atomic misfit and modulus misfit, and the results indicated the degree of solid solution could affect the estimation accuracy.

Automated summary

A novel lightweight refractory high entropy alloys AlxCrNbTiV have been prepared by vacuum arc melting. The alloys exhibit a BCC phase with significant dendrite structure and a low density. The addition of Al enhances the hardness of the alloys. Al0.2CrNbTiV alloy shows a good combination of strength and ductility at room temperature, while Al0.5CrNbTiV and Al0.8CrNbTiV alloys exhibit typical brittle behavior. The hot compression process activates both DDRX and CDRX, resulting in softening and increased ductility of the alloys. The theoretical yield stress of AlxCrNbTiV is calculated, indicating that the degree of solid solution affects the accuracy of estimation.