Solving oxygen embrittlement of refractory high-entropy alloy via grain boundary engineering

Refractory high-entropy alloys (RHEAs), particularly NbMoTaW RHEAs, exhibit outstanding softening resistance and thermal stability at ultra-high temperatures, but suffer from room-temperature brittleness, which severely limits their processability and thus practical application. In this study, we successfully achieved large plasticity of >10%, along with high strength of >1750 MPa in the NbMoTaW RHEAs via grain boundary engineering with the addition of either metalloid B or C. It was revealed that the room-temperature brittleness of the as-cast NbMoTaW RHEA originates from the grain-boundary segregation of the oxygen contaminant which weakens grain-boundary cohesion. The doped small-sized metalloids preferentially replace oxygen at grain boundaries and promote stronger electronic interaction with the host metals, which effectively alleviates the grain boundary brittleness and changes the fracture morphology from intergranular fracture to transgranular fracture. Our findings not only shed light on the understanding of the embrittlement mechanism of RHEAs in general, but also offer a useful route for ductilization of brittle HEAs.

Automated summary

In this study, large plasticity and high strength were achieved in NbMoTaW RHEAs through grain boundary engineering and the addition of metalloid B or C. The room-temperature brittleness of as-cast NbMoTaW RHEA was found to be caused by grain boundary segregation of oxygen, which was alleviated by the added metalloids, leading to a change in fracture morphology.