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Promoted room-temperature deformability and high-temperature strength synergy through zig-zag faceted interface design in TiNbTaWC0.7 eutectic refractory high-entropy alloy

Yusheng Tian, Beiya Wang, Dongyu Wei, Decheng Kong, Rui Wang, Guoliang Zhu, Baode Sun

2024Journal of Materials Research and Technology15 citationsDOIOpen Access PDF

Abstract

With the development of aerospace technologies, there is an urgent demand for materials with better high-temperature performance. Despite the bottleneck of combining high-temperature strength and room-temperature deformability, refractory high-entropy alloys are potential candidates. Here, we report a novel alloy, TiNbTaWC 0.7 , with a good strength-ductility synergy by introducing the eutectic carbide phase. The alloy is composed of alternated BCC matrix phase and FCC carbide phase, forming a fully eutectic microstructure. With the introduction of the eutectic carbides, the alloy is robust at 1200 °C. The faceted phase interface together with the compositional complex carbides provides the alloy with good deformation ability at room temperature. The former promotes dislocation nucleation and transmission, and the latter generates stacking faults by partial dislocation movement. This strategy provides a new route to design promising high-temperature structural materials by combining the advantages of eutectic alloy, carbide strengthening, and refractory alloys utilizing the high entropy concept.

Topics & Concepts

Materials scienceEutectic systemAlloyRefractory (planetary science)MetallurgyHigh entropy alloysComposite materialHigh Entropy Alloys StudiesHigh-Temperature Coating BehaviorsIntermetallics and Advanced Alloy Properties
Promoted room-temperature deformability and high-temperature strength synergy through zig-zag faceted interface design in TiNbTaWC0.7 eutectic refractory high-entropy alloy | Litcius