Graphene-enhanced tribological behavior of CuCr alloys: a molecular dynamics study on wear resistance and friction mechanisms
ZX Xing and JZ Zhu and J Wang and HW Ren and ZY Han and QM Li, JOURNAL OF PHYSICS D-APPLIED PHYSICS, 58, 355503 (2025).
DOI: 10.1088/1361-6463/adfdf3
During high-strain and high-friction working conditions, electrical contact materials often face severe challenges from mechanical wear, which can lead to surface material failure, thereby endangering the stability of the friction pair system. As a result, there is an urgent need to develop high-performance anti-wear materials. Graphene, a two- dimensional self-lubricating material, possesses excellent mechanical and electrical properties, making it highly promising for use in metal tribological modifications. This study utilizes the CuCr30 alloy, a common material in the field of electrical contacts, as the matrix to create composite models reinforced with varying mass fractions of graphene. Molecular dynamics simulations are used to clarify the evolution characteristics of its tribological properties, and friction experiments are conducted to validate the simulation results. The findings demonstrate that graphene reinforcement significantly enhances the tribological performance of CuCr alloys. As the graphene content increases, both the coefficient of friction (COF) and wear rate decrease in tandem. Specifically, the CuCr30Gr1 alloy shows reductions of 51.40% in COF, 56.90% in atomic wear area, and 74.93% in wear rate when compared to the unmodified CuCr matrix. Mechanistic analysis reveals that the high-rigidity framework of graphene hinders dislocation propagation within the matrix. The strong C-C bonds restrain tangential slip of matrix atoms, transforming normal displacement into wrinkling deformation of carbon rings. This significantly elevates the energy barrier for dislocation slip, thereby enhancing the alloy's resistance to plastic deformation. This study provides a detailed understanding of the microscopic wear resistance mechanisms of CuCr30Gr composites, offering both theoretical insights and technical guidance for the development of high-performance wear-resistant CuCr alloys for electrical contact applications.
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