Uniaxial stress-driven coupled grain boundary motion in hexagonal close-packed metals: A molecular dynamics study

IF 9.3 1区材料科学 Q1 MATERIALS SCIENCE, MULTIDISCIPLINARY

Acta Materialia Pub Date : 2015-01-01 DOI:10.1016/j.actamat.2014.09.010

Hongxiang Zong , Xiangdong Ding , Turab Lookman , Ju Li , Jun Sun

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引用次数: 29

Abstract

Stress-driven grain boundary (GB) migration has been evident as a dominant mechanism accounting for plastic deformation in crystalline solids. Using molecular dynamics (MD) simulations on a Ti bicrystal model, we show that a uniaxial stress-driven coupling is associated with the recently observed 90° GB reorientation in shock simulations and nanopillar compression measurements. This is not consistent with the theory of shear-induced coupled GB migration. In situ atomic configuration analysis reveals that this GB motion is accompanied by the glide of two sets of parallel dislocation arrays, and the uniaxial stress-driven coupling is explained through a composite action of symmetrically distributed dislocations and deformation twins. In addition, the coupling factor is calculated from MD simulations over a wide range of temperatures. We find that the coupled motion can be thermally damped (i.e., not thermally activated), probably due to the absence of the collective action of interface dislocations. This uniaxial coupled mechanism is believed to apply to other hexagonal close-packed metals.

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六方密排金属中单轴应力驱动的耦合晶界运动:分子动力学研究

应力驱动的晶界(GB)迁移是导致结晶固体塑性变形的主要机制。通过对Ti双晶模型的分子动力学(MD)模拟，我们发现单轴应力驱动耦合与最近在冲击模拟和纳米柱压缩测量中观察到的90°GB重定向有关。这与剪切诱导的耦合GB迁移理论不一致。原位原子构型分析表明，这种GB运动伴随着两组平行位错阵列的滑动，并且通过对称分布的位错和变形孪晶的复合作用来解释单轴应力驱动耦合。此外，耦合因子是在一个很宽的温度范围内从MD模拟计算。我们发现耦合运动可能是热阻尼的(即，不是热激活的)，这可能是由于没有界面位错的集体作用。这种单轴耦合机制也适用于其他六方密排金属。

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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来源期刊

Acta Materialia 工程技术-材料科学：综合

CiteScore

16.10

自引率

8.50%

发文量

801

审稿时长

53 days

期刊介绍： Acta Materialia serves as a platform for publishing full-length, original papers and commissioned overviews that contribute to a profound understanding of the correlation between the processing, structure, and properties of inorganic materials. The journal seeks papers with high impact potential or those that significantly propel the field forward. The scope includes the atomic and molecular arrangements, chemical and electronic structures, and microstructure of materials, focusing on their mechanical or functional behavior across all length scales, including nanostructures.