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A high-entropy high-temperature shape memory alloy with large and complete superelastic recovery

Shaohui Li, Daoyong Cong, Zhen Chen, Shengwei Li, Chao Song, Yuxian Cao, Zhihua Nie, Yandong Wang

2021Materials Research Letters63 citationsDOIOpen Access PDF

Abstract

High-temperature shape memory alloys (HTSMAs) show enormous potential for applications as energy conversion devices, actuators and sensors in automotive, aerospace, and energy exploration industries, but they suffer from strength decrease and microstructural instability at elevated temperatures, rendering it difficult to achieve satisfactory high-temperature superelasticity. Here, a novel Ti20Hf15Zr15Cu25Ni25 high-entropy HTSMA exhibiting large superelasticity with a fully recoverable strain of 4.0% at temperatures up to 285°C is designed with the high-entropy alloy concept by employing the sluggish diffusion and severe lattice distortion effects to suppress thermal softening. This work illuminates the design of novel high-performance functional materials for high-temperature applications.

Topics & Concepts

PseudoelasticityMaterials scienceHigh entropy alloysShape-memory alloyAlloyHigh energyActuatorComposite materialEngineering physicsMicrostructureMartensiteComputer scienceEngineeringArtificial intelligenceHigh Entropy Alloys StudiesShape Memory Alloy Transformations