材料科学
石墨烯
铜
复合材料
热压
热导率
润湿
碳纤维
复合数
冶金
纳米技术
作者
Shengcheng Shu,Qilong Yuan,Wen Dai,Mingliang Wu,Dan Dai,Ke Yang,Bo Wang,Cheng‐Te Lin,Thomas Wuebben,Jost Degenhardt,Christoph Regula,Ralph Wilken,Nan Jiang,Jörg Ihde
标识
DOI:10.1016/j.matdes.2021.109586
摘要
Owing to the unfavorable wetting and density difference between graphene and copper, it remains challenging to achieve homogeneous dispersion of graphene for utilizing the unique nature of graphene in copper matrix composites. Here, we design an in-situ process to fabricate graphene-like carbon (GLC) reinforcing copper matrix composites: GLC can be directly fabricated on commercial copper particles using modified PECVD method followed by vacuum hot pressing, which is high-efficiency and can be massively produced for graphene reinforced metal matrix composites in industrial level. After hot pressing, the GLC with ultralow content (170 to 350 ppm) can be uniformly dispersed and tightly embedded within the copper matrix. A remarkable thermal conductivity enhancement efficiency of 85% and enhanced thermal conductivity (439 W m−1 K−1), accompanied by the higher wear resistance, can be obtained in our GLC reinforced copper matrix composites. In actual arc ablation performance measurement, the breakdown strength and relative arc ablation resistance of GLC/Cu composites can be significantly improved by 106.5% and 33.3% than pure copper, respectively, demonstrating GLC/Cu composites a promising candidate for application as high voltage electrical contacts.
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