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Concurrent enhancement in mechanical properties and oxidation resistance of AlCrMoNbTi RHEAs via Cr addition

Xiang Guo, Junjun Wang, Zijian Geng, Zhengfa He, Jian Peng, Zhigang Xu, Wenjun Li, Chuanbin Wang

2025Journal of Materials Research and Technology12 citationsDOIOpen Access PDF

Abstract

Concurrent enhancement in mechanical properties and oxidation resistance of AlCrMoNbTi refractory high-entropy alloys was achieved via Cr addition. The effects of Cr content on its phase, microstructure, mechanical properties, and high-temperature oxidation resistance of AlCr x MoNbTi ( x = 1, 1.2, 1.4, 1.6, 1.8, 2, 2.2) RHEAs were elucidated. After Cr addition, AlCrMoNbTi, which was originally in a BCC structure, contains both BCC and C14 phases. Consequently, the hardness increased monotonically with increasing Cr content, reaching the maximum of 781 Hv at AlCr 2.2 MoNbTi, 44.6% higher than AlCrMoNbTi. Cr addition also enhanced the compression yield strength and fracture strain. Those of AlCr 2 MoNbTi reach 2122 MPa and 7.52%, respectively, 55.1% and 37.2% higher than those of AlCrMoNbTi. The formation of the Laves phase is believed to be responsible for the enhancement in compression yield strength, while the improvement in fracture strain is mainly due to grain boundary strengthening. Notably, the specific yield strength of AlCr 2 MoNbTi reached 322 MPa cm 3 g −1 , which is superior to that of lighterweight RHEAs. In addition, Cr addition promoted the isothermal oxidation resistance of AlCr x MoNbTi RHEAs. The mass gain per unit area of AlCr 2 MoNbTi was reduced to 3.3 mg cm −2 after 50 h oxidation at 1000 °C, primarily attributed to the formation of Cr 2 O 3 , which serves as an effective barrier against oxygen diffusion, and the formation of the AlNbO 4 phase, which effectively mitigate the oxidation of Mo.

Topics & Concepts

Materials scienceResistance (ecology)Chemical engineeringComposite materialNanotechnologyBiologyEcologyEngineeringHigh Entropy Alloys StudiesHigh-Temperature Coating BehaviorsIntermetallics and Advanced Alloy Properties