Martensitic Transformation Mechanism of Mg-Sc Lightweight Shape Memory Alloys

Wenbin Zhao, Kun Zhang, E. Guo, Lei Zhao, X. Tian, Chang-long Tan
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引用次数: 7

Abstract

Abstract Mg-Sc alloys are known as novel and promising lightweight shape memory alloys (LWSMAs), which have outstanding performance. Yet, a precise understanding of the microscopic picture and interactions governing the martensitic transformation (MT) remains elusive. We systematically investigate the MT of Mg-Sc alloys using first-principles methods. The result of generalized solid-state nudged elastic band methods confirms that no energy barrier inhibits the MT. We show that the bcc structure of Mg26Sc6 is dynamical instability at 0 K caused by electron-phonon coupling and Fermi surface nesting. Particularly, the high-temperature stability of Mg26Sc6 is revealed for the first time using the temperature-dependent effective potential method. The softening of the acoustic mode at Γ-R corresponds to two neighboring (1 0 1) planes moving towards each other, and forms martensite phase. Our calculations provide the complete and atomic-level mechanism for the MT of Mg-Sc alloys and shed some light on the design of new LWSMAs.
Mg-Sc轻量化形状记忆合金马氏体相变机理研究
摘要Mg-Sc合金是一种具有优异性能的新型轻量化形状记忆合金。然而,对微观图像和控制马氏体相变(MT)的相互作用的精确理解仍然是难以捉摸的。本文采用第一性原理方法系统地研究了Mg-Sc合金的MT。广义固体轻推弹性带方法的结果证实了没有能量势垒抑制MT。我们证明了Mg26Sc6的bcc结构在0 K时是由电子-声子耦合和费米表面嵌套引起的动态不稳定性。特别是,利用温度相关有效电位法首次揭示了Mg26Sc6的高温稳定性。声波模式在Γ-R处的软化对应于相邻的两个(1 0 1)平面相互移动,形成马氏体相。我们的计算提供了Mg-Sc合金MT的完整的原子水平机制,并为新型lwsma的设计提供了一些启示。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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