Microstructure evolution and mechanical properties of FeCoCrNiCuTi0.8 high-entropy alloy prepared by directional solidification

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Abstract

A CoCrCuFeNiTi0.8 high-entropy alloy was prepared using directional solidification techniques at different withdrawal rates (50 μm/s, 100 μm/s, 500 μm/s). The results showed that the microstructure was dendritic at all withdrawal rates. As the withdrawal rate increased, the dendrite orientation become uniform. Additionally, the accumulation of Cr and Ti elements at the solid/liquid interface caused the formation of dendrites. Through the measurement of the primary dendrite spacing (λ1) and the secondary dendrite spacing (λ2), it was concluded that the dendrite structure was obviously refined with the increase in the withdrawal rate to 500 μm/s. The maximum compressive strength reached 1449.8 MPa, and the maximum hardness was 520 HV. Moreover, the plastic strain of the alloy without directional solidification was 2.11%, while the plastic strain of directional solidification was 12.57% at 500 m/s. It has been proved that directional solidification technology can effectively improve the mechanical properties of the CoCrCuFeNiTi0.8 high-entropy alloy.

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Xu, Y., Li, C., Huang, Z., Chen, Y., & Zhu, L. (2020). Microstructure evolution and mechanical properties of FeCoCrNiCuTi0.8 high-entropy alloy prepared by directional solidification. Entropy, 22(7). https://doi.org/10.3390/e22070786

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