Synergetic Deformation Mechanism in Hierarchical Twinned High-Entropy Alloys

Materials Engineering eJournal Pub Date : 2021-08-01 DOI:10.2139/ssrn.3834125

Wenjun Lu, Jianjun Li

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引用次数: 6

Abstract

Abstract The mechanical properties of crystalline materials can be efficiently optimized using a hierarchical twinned structure. Conventional deformation mechanisms for coherent Σ3 boundaries generally involve three basic models: cross-slip, partial dislocation step, and full dislocation step. In this study, we report a novel deformation mechanism that allows the co-existence of twin-separation, phase transformations, grain rotation, and cracking, around a triple junction of twin boundaries in a hierarchical twinned high-entropy alloy. The deformation mechanisms in the reference high-entropy alloy (Fe-30Mn-10Co-10Cr at. %) were investigated using LAADF-STEM. The triple junction of the hierarchical twinned structure gradually deformed during in-situ strain and showed mechanisms significantly different from that observed in the purely twinned structures. These new mechanisms are referred to as “novel synergetic deformation mechanisms of hierarchical twin boundaries.” Understanding the fundamental mechanisms of the hierarchical twin boundaries under deformation could assist the design of strong and ductile bulk materials with hierarchical twinned structure.

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分层孪晶高熵合金的协同变形机制

利用分层孪晶结构可以有效地优化晶体材料的力学性能。相干Σ3边界的传统变形机制一般包括三种基本模型:交叉滑移、部分位错阶跃和完全位错阶跃。在这项研究中，我们报告了一种新的变形机制，该机制允许在分层孪晶高熵合金的孪晶边界的三重结周围共存孪晶分离，相变，晶粒旋转和裂纹。研究了参考高熵合金(Fe-30Mn-10Co-10Cr)的变形机理。%)使用LAADF-STEM进行调查。分层孪晶结构的三重结在原位应变过程中逐渐变形，表现出与纯孪晶结构明显不同的机制。这些新的机制被称为“分层孪晶界的新型协同变形机制”。了解分层孪晶边界在变形作用下的基本机理，有助于设计具有分层孪晶结构的高韧性块体材料。

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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Materials Engineering eJournal

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