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

doi:10.1080/21663831.2021.1893233

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

^*Corresponding author for this work

School of Material Science and Engineering

University of Science and Technology Beijing

Research output: Contribution to journal › Article › peer-review

39 Citations (Scopus)

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.

Original language	English
Pages (from-to)	263-269
Number of pages	7
Journal	Materials Research Letters
Volume	9
Issue number	6
DOIs	https://doi.org/10.1080/21663831.2021.1893233
Publication status	Published - 2021

Keywords

High entropy alloys
lattice distortion
martensitic transformation
shape memory effect
superelasticity

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10.1080/21663831.2021.1893233

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title = "A high-entropy high-temperature shape memory alloy with large and complete superelastic recovery",

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.",

keywords = "High entropy alloys, lattice distortion, martensitic transformation, shape memory effect, superelasticity",

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

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T1 - A high-entropy high-temperature shape memory alloy with large and complete superelastic recovery

AU - Li, Shaohui

AU - Cong, Daoyong

AU - Chen, Zhen

AU - Li, Shengwei

AU - Song, Chao

AU - Cao, Yuxian

AU - Nie, Zhihua

AU - Wang, Yandong

PY - 2021

Y1 - 2021

N2 - 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.

AB - 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.

KW - High entropy alloys

KW - lattice distortion

KW - martensitic transformation

KW - shape memory effect

KW - superelasticity

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DO - 10.1080/21663831.2021.1893233

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SP - 263

EP - 269

JO - Materials Research Letters

JF - Materials Research Letters

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

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Keywords

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