The corrosion resistance behavior of Cu/10vol.% SiC copper matrix composites with different graphite volume fractions ranging from 2.5 to 7.5vol.% was investigated in 3.5wt.%sodium chloride (NaCl) aqueous solution and compared to the behavior of pure copper. All the materials were fabricated by a hot pressing technique. Both salt immersion and electrochemical polarization measurements were made, and the surface morphology and composition after corrosion tests were examined. The results indicate that the graphite addition had an adverse effect on the formation of the surface passive film; Cu/10vol. % SiC/7.5vol.% Graphite was the worst, whereas pure copper possessed the best protective surface film. Evidence further showed that the composites Cu/SiC/Graphite exhibited crevice attack at the copper matrix-SiC reinforcement interface and galvanic corrosion attack at the graphite-copper matrix boundary, which made SiC particles peeling and copper matrix pitting seriously. Moreover, the presence of dissolved oxygen enhanced the corrosion severity, the corrosion rate of both reinforced composites and unreinforced pure copper in aerated chloride solution was higher than that in deaerated chloride solution. In addition, it was also found that the composites exhibited higher corrosion loss over the pure copper, and weight loss increased with increasing graphite contents and exposure time.