Microstructure and Electrical Resistivity of In Situ Cu-Fe Microcomposites

被引：0

作者：

Keming Liu

Xiaochun Sheng

Guangyu He

Ningle Han

Mulin Li

Mengcheng Zhang

Jin Zou

Andrej Atrens

Huiming Huang

机构：

[1] Nanchang Institute of Technology,Jiangxi Key Laboratory for Precision Actuation and Control

[2] Jiangxi Academy of Sciences,Institute of Applied Physics

[3] The University of Queensland,Centre for Advanced Materials Processing and Manufacturing

来源：

Journal of Materials Engineering and Performance | 2022年 / 31卷

关键词：

Cu-Fe; electrical resistivity; evolution; microcomposite; microstructure;

D O I：

暂无

中图分类号：

学科分类号：

摘要：

This paper studied the electrical resistivity of in situ Cu-Fe microcomposites using theoretical analysis and experiments. The model alloys Cu-XFe (X = 3, 4.3, 11, 14 and 17 wt.%) were produced by casting, and the microcomposites were prepared by thermomechanical treatment. The solid solubility of iron in the copper matrix was measured using an energy dispersive spectrometer. The electrical resistivity and conductivity was evaluated using a micro-ohmmeter. The conductivity of the Cu-XFe (X = 3 and 4.3) was essentially constant at ~ 40% IACS. The conductivity of the Cu-XFe (X = 11, 14, 17) microcomposites decreased in a nonlinear manner with increasing iron content and increasing cold deformation strain, which was mainly determined by the interface scattering resistivity caused by the interface between the copper matrix and the iron fibers.

引用

页码：3896 / 3901

页数：5

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