Investigation on the dual-phase co-deformation behavior and strengthening mechanism in cold-drawn Cu–20Fe alloy

In this work, cold drawing deformation was applied aiming to achieve a good combination of strength and electrical conductivity of Cu–20Fe alloy, and also such underlying mechanisms for microstructure evolution and strengthening, as well as variation in conductivity were clarified. It is also found...

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Published in:Materials science & engineering. A, Structural materials : properties, microstructure and processing Structural materials : properties, microstructure and processing, 2023-01, Vol.862, p.144474, Article 144474
Main Authors: Yue, Shipeng, Li, Guoliang, Qu, Jianping, Liu, Shichao, Guo, Zhongkai, Jie, Jinchuan, Guo, Shengli, Li, Tingju
Format: Article
Language:English
Subjects:
Cobalt base alloys
Cold drawing
Cold drawn
Copper
Cu-20Fe alloy
Deformation
Electrical resistivity
Fibrous structure
Grains
High density
Iron
Mechanical property
Microstructure evolution
Strengthening
Strengthening mechanism
Texture
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Summary:In this work, cold drawing deformation was applied aiming to achieve a good combination of strength and electrical conductivity of Cu–20Fe alloy, and also such underlying mechanisms for microstructure evolution and strengthening, as well as variation in conductivity were clarified. It is also found that both Cu matrix grains and Fe-rich dendrites can be significantly refined and transformed into fibrous structure with increasing of drawing strain. The average size of Cu grains and thickness of Fe fiber are 0.47 ± 0.05 μm and 25 ± 5 nm, respectively for alloy subjected to the drawing strain of η = 5.78. In addition, the Fe dendrites exhibit a strong fiber texture, while the corresponding Cu matrix forms a fiber texture. It is demonstrated that the excellent properties with the yield strength of 1173 MPa and the electrical conductivity of 41 %IACS can be reached for cold-drawn Cu–20Fe alloy. In addition, the quantitative analysis on strengthening contributions shows that the high strength of as-drawn Cu–20Fe alloy is dominantly originated from high-density Fe fibers. Meanwhile, the lower electrical conductivity is ascribed to the high solute Fe content and high-density Cu/Fe heterogeneous phase interface. •The microstructure evolution and properties of Cu–20Fe alloys at different drawing strains were clearly elucidated.•The Cu–Fe dual-phase co-deformation behavior during drawing deformation process was described.•A strengthening model of Cu–Fe dual phase alloy under severe plastic deformation was established.•The Cu–20Fe alloy achieves a good combination of mechanical and electrical properties at drawing strain of η = 5.78.
ISSN:0921-5093
1873-4936
DOI:10.1016/j.msea.2022.144474