Development of High-Entropy Shape-Memory Alloys: Structure and Properties

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Abstract

Amongst functional materials, shape-memory alloys occupy a special place. Discovered in the beginning of 1960th in XX century, these alloys attracted quite an attention because of the possibility to restore significant deformation amounts at certain stress–temperature conditions due to the martensitic diffusionless phase transformation involved in a process. It was possible to exploit not only so-called ‘shape-memory’ effect, but also superelasticity and high damping capacity. Over the years, more than 10 000 patents on shape-memory alloys were filed, appreciating not only the possibility to exploit energy transformation to ensure the response (feedback) at the change in independent thermodynamic parameters (temperature, stress, pressure, electric or magnetic field, etc.), but the significant work output as well. Applications ranged from different gadgets to automotive, aerospace industries, machine building, civil construction, etc. Unfortunately, the structural and functional fatigue restricted successful business application to medical sector with nitinol shape-memory alloy (different implants, stents, cardiovascular valves, etc.). Emerging high-entropy shape-memory alloys can be considered as a chance to overcome fatigue problems of existing industrial shape-memory alloys due to their specific structure that ensures superior resistance to irreversible plastic deformation.
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开发高熵形状记忆合金:结构与性能
在功能材料中,形状记忆合金占有特殊的地位。这种合金在二十世纪六十年代初被发现,由于在加工过程中发生了马氏体无扩散相变,因此在一定的应力-温度条件下可以恢复显著的变形量,因而引起了广泛关注。不仅可以利用所谓的 "形状记忆 "效应,还可以利用超弹性和高阻尼能力。多年来,有关形状记忆合金的专利申请已超过 10 000 项,这些专利不仅重视利用能量转换的可能性,以确保在独立热力学参数(温度、应力、压力、电场或磁场等)发生变化时做出响应(反馈),而且还重视显著的工作输出。其应用范围从不同的小工具到汽车、航空航天工业、机械制造、民用建筑等。遗憾的是,结构和功能疲劳限制了镍钛诺形状记忆合金在医疗领域(各种植入物、支架、心血管瓣膜等)的成功应用。新出现的高熵形状记忆合金因其特殊的结构可确保卓越的抗不可逆塑性变形能力,可被视为克服现有工业形状记忆合金疲劳问题的契机。
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