Modeling core-spreading of interface dislocation and its elastic response in anisotropic bimaterial

被引:0
作者
Jie Liu
Yuheng Zhang
Haijian Chu
机构
[1] Shanghai University,Shanghai Institute of Applied Mathematics and Mechanics, and Shanghai Key Laboratory of Mechanics in Energy Engineering
[2] Shanghai University,Department of Mechanics, College of Sciences
来源
Applied Mathematics and Mechanics | 2017年 / 38卷
关键词
interface dislocation; core spreading; elastic field; anisotropic bimaterial; O77; 2; 74M25; 74G05; 74L99;
D O I
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中图分类号
学科分类号
摘要
Interfacial dislocation may have a spreading core corresponding to a weak shear resistance of interfaces. In this paper, a conic model is proposed to mimic the spreading core of interfacial dislocation in anisotropic bimaterials. By the Stroh formalism and Green’s function, the analytical expressions of the elastic fields are deduced for such a dislocation. Taking Cu/Nb bimaterial as an example, it is demonstrated that the accuracy and efficiency of the method are well validated by the interface conditions, a spreading core can greatly reduce the stress intensity near the interfacial dislocation compared with the compact core, and the elastic fields near the spreading core region are significantly different from the condensed core, while they are less sensitive to a field point that is 1.5 times the core width away from the center of the spreading core.
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页码:231 / 242
页数:11
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