Ultrastrong and ductile NiTi-based composite with large recoverable strain mediated by a compositionally complex phase

IF 7.2 2区 材料科学 Q1 MATERIALS SCIENCE, MULTIDISCIPLINARY Applied Materials Today Pub Date : 2024-07-23 DOI:10.1016/j.apmt.2024.102347
Jiayi Geng, Yunzhu Shi, Pere Barriobero-Vila, Meiyuan Jiao, Yihuan Cao, Yu Tang, Jingzhi He, Chao Ma, Yan Ma, Zhifeng Lei, Zhaoping Lu
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Abstract

NiTi-based composites possess great potential for concurrently improving both mechanical and functional properties. However, relying on traditional alloy design principles limits the design space and greatly hinders the advancement of high-performance NiTi-based composites. The concept of high-entropy alloys has expanded the compositional landscape, unveiling unique structural characteristics for alloy design and providing new prospects for addressing these limitations. Here, we report a compositionally complex NiTi-based composite that exhibits exceptional strength and ductility, along with remarkable recoverable strain. The composite, NiTi(NbMoTaW) (at.%), comprises a 78.0 % B2 NiTi matrix, a 19.2 % Nb-Mo-Ta-W-Ti-Ni compositionally complex body-centered cubic (BCC) phase, and a small amount of TiNi. Notably, this composite demonstrates an engineering compressive strength of 3274 MPa, with a compressive fracture strain of 44.2 % and a maximum recoverable strain of 7.3 % (5.6 % elastic strain and 1.7 % inelastic recoverable strain). These outstanding mechanical properties result from the unique structural characteristics of the compositionally complex phase and the lattice strain matching induced by phase transitions. The substantial recoverable strain was obtained through the reversible B2⇌R⇌B19′ phase transition. This work not only innovates a new category of high-performance NiTi-based composites but also extends the applicability of the high-entropy concept.
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超强韧性镍钛基复合材料,在成分复杂相的介导下具有较大的可恢复应变
镍钛基复合材料具有同时提高机械性能和功能特性的巨大潜力。然而,依靠传统的合金设计原则限制了设计空间,极大地阻碍了高性能镍钛基复合材料的发展。高熵合金的概念拓展了成分领域,为合金设计揭示了独特的结构特征,并为解决这些限制提供了新的前景。在此,我们报告了一种成分复杂的镍钛基复合材料,它具有优异的强度和延展性,以及显著的可恢复应变。这种名为 NiTi(NbMoTaW) (at.%) 的复合材料由 78.0 % 的 B2 NiTi 基体、19.2 % 成分复杂的 Nb-Mo-Ta-Wi-Ti-Ni 体心立方 (BCC) 相和少量 TiNi 组成。值得注意的是,这种复合材料的工程抗压强度为 3274 兆帕,压缩断裂应变为 44.2%,最大可恢复应变为 7.3%(5.6% 弹性应变和 1.7% 非弹性可恢复应变)。这些出色的机械性能源于成分复杂相的独特结构特征和相变引起的晶格应变匹配。大量的可恢复应变是通过可逆的 B2⇌R⇌B19′ 相变获得的。这项工作不仅开创了高性能镍钛基复合材料的新类别,还扩展了高熵概念的适用范围。
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来源期刊
Applied Materials Today
Applied Materials Today Materials Science-General Materials Science
CiteScore
14.90
自引率
3.60%
发文量
393
审稿时长
26 days
期刊介绍: Journal Name: Applied Materials Today Focus: Multi-disciplinary, rapid-publication journal Focused on cutting-edge applications of novel materials Overview: New materials discoveries have led to exciting fundamental breakthroughs. Materials research is now moving towards the translation of these scientific properties and principles.
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