Low cycle fatigue performances of Al0.3CoCrFeNi high entropy alloys: In situ neutron diffraction studies on the precipitation effects.

Fatigue properties are essential for structural materials in industrial applications. High-entropy alloys are promising fatigue-resistant alloys with high strengths and good ductilities. In this study, the B2 precipitate significantly increased the yield strength of the Al 0.3 CoCrFeNi high-entropy alloy but at the same time decreased the low-cycle fatigue life. A detailed investigation of the underlying mechanisms will provide critical insights into the precipitate effect on the fatigue performance of high-entropy alloys. Here, the Al 0.3 CoCrFeNi alloys with single face-centered-cubic (FCC) phase and with FCC + B2 phases are used for the investigation of the low-cycle fatigue behavior by combining in situ neutron diffraction measurements and elastic-viscoplastic self-consistent modeling. The simulation results indicate that the B2 precipitates highly increased the back stresses during cyclic loading by facilitating the kinematic hardening in the matrix, while the effect of dynamic recovery is relatively weak. The increase in back stresses provides more fatigue-crack-initiation sites and thus the damage accumulation, which will further lead to a shorter fatigue life. [Display omitted] • The B2 precipitates increased the yield strength and decrease the LCF life in the Al 0.3 CoCrFeNi HEA. • Lattice strain and full-width half-maximum results were obtained from in situ neutron diffraction. • Diffraction experiments and crystal plasticity modeling reveal the role played by B2 precipitates. [ABSTRACT FROM AUTHOR]