High temperature oxidation resistance of AlMoxNbTayTiZr refractory high entropy alloys fabricated by laser additive manufacturing

high entropy alloys have excellent high temperature mechanical properties, but the high temperature oxidation resistance has always been one of the limiting factors in their application. Four kinds of refractory high entropy alloys AlNbTaTiZr, AlMoNbTiZr, AlMoNbTaTiZr and AlMo0.5NbTa0.5TiZr were designed and prepared by laser additive manufacturing technology. The oxidation mass gain of AlNbTiZrbased refractory high entropy alloys was measured at 900 degrees C and 1000 degrees C, and the oxidation layer structure of different samples was studied. The effects of Mo and Ta on the high temperature oxidation resistance of AlNbTiZr-based refractory high entropy alloys were compared and analyzed. The results show that the four kinds of as-deposited high entropy alloys prepared by laser additive manufacturing are BCC+HCP dual-phase structures. The dendrites are mainly BCC phases with high melting points, and a small amount of HCP phase rich in Al and Zr is distributed among the dendrites. AlNbTaTiZr shows the best oxidation resistance after oxidation at 900 degrees C and 1000 degrees C for a long time, and Ta instead of Mo to some extent improves the oxidation resistance of refractory high entropy alloys.