Due to its excellent electrical conductance, copper is usually used as interconnect and metallization materials. However, surface copper oxide layer readily forms during fabrication or assembly processes. Electrical resistance will thus increases and even causes device failure problems. For instance, formation of copper oxides plays an important role in the delamination between epoxy molding compounds (EMC) and lead frames. The type and thickness of surface oxide layer, as well as the ratio of CuO/Cu_2O are all affecting factors. How to efficiently and precisely identify the oxide phases and measure the oxide thickness is very crucial. In this study, the analysis of oxidized layer of electroplated copper and cold rolled copper by means of electrochemical and optical methods are developed. Isothermal heating simulating fabrication processes, such as molding and curing, is carried out to obtain different oxidation conditions. Coulometric reduction method and FTIR (Fourier transform infrared spectroscopy) are adopted to analyze the surface oxide layer. According to the absorption peaks of FTIR curves, the oxidized surface can be easily identified. In combination with the reduction potential and reduction time obtained from the coulometric reduction test, the variation of oxide phases along the through-thickness direction can also be revealed.