Molecular dynamics study on the deformation mechanism of Cu-Zr/Al laminated composites

MD Wang and JP Zhang and AQ Wang and TT Liang and JP Xie, JOURNAL OF MATERIALS RESEARCH AND TECHNOLOGY-JMR&T, 33, 3894-3900 (2024).

DOI: 10.1016/j.jmrt.2024.10.089

In this paper, molecular dynamics simulation was used to investigate the micromechanical behavior of the Cu-Zr/Al composite interface after rapid solidification. The effects of different Zr contents and different strain rates on the tensile strength of the Cu-Zr/Al composite interface were investigated. The results show that the tensile strength of the composite plate increased and then decreased with the increase of Zr content, and the tensile strength is the highest when the Zr content is 0.33 wt%. It was found that the plastic deformation process of the composite model at different strain rates is similar, which is divided into three stages: the expansion of stacking faults in the Cu-Zr/Al solid solution, the expansion of stacking faults successively in the Al and Cu-Zr alloy layers, and the spreading of cross- stacking faults. But the greater the strain rate is, the slower the stacking faults fracture is. So the composite model with different strain rates had different fracture modes during the tensile fracture process. When the strain rate is 0.01 ps(-1) and 0.001 ps(-1) , it is a ductile fracture, while when the strain rate is 0.0001 ps(-1) , it is a brittle fracture.

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