Surface modification on copper particles toward graphene reinforced copper matrix composites for electrical engineering application

Graphene has been demonstrated as an effective reinforcement for metal matrix composites, due to its excellent mechanical properties, robust chemical inertness, thermal stability, and self-lubricating. Nevertheless, the limiting factor for its further use in metal matrix composites, is to realize the homogeneous dispersion of graphene for taking advantage of its exceptional and fascinating properties, because of the poor wettability and density contrast between metal matrix and graphene. Herein, we design a gel assisted route to synthesize high-quality graphene nanoplatelets modified monodispersed copper particles, followed by hot pressing to fabricate graphene reinforced copper matrix composites bulk. This simple route with high efficiency and low cost, offers a new solution for the mass-production of graphene reinforced copper matrix composites and other graphene-based composites on an industrial scale. Significantly enhanced tensile strength of 253 MPa, and yield strength of 145 MPa, accompanied by the low friction coefficient and improved wear resistance, can be simultaneously achieved in the composites. For the real electrical contact performance test, the service life of electrical contacts made of graphene reinforced copper matrix composites, is 10 times longer as that of the commercial pure copper electrical contacts and almost comparable to CuAg20 contacts, demonstrating its superior ability to solve the electrical contact issues in electrical engineering systems. (c) 2021 Elsevier B.V. All rights reserved.

Automated summary

Graphene has shown promise as an effective reinforcement for metal matrix composites due to its exceptional properties, but achieving uniform dispersion remains a challenge. A gel-assisted route was designed to produce graphene-reinforced copper matrix composites with significantly enhanced mechanical properties, low friction coefficient, and improved wear resistance, offering a new solution for mass production of graphene-based composites.