Quantitative In Situ Analysis of Initial Atmospheric Corrosion of Copper Induced by Acetic Acid

Abstract

The initial atmospheric corrosion of copper was investigated by means of a quantitative in situ analysis in an atmosphere containing of acetic acid and 95% relative humidity using a quartz crystal microbalance (QCM) integrated with infrared reflection absorption spectroscopy (IRAS). Crystalline cuprous oxide (various structural forms of ) and hydrated copper acetate were detected as corrosion products during up to of exposure. The quantification of data was made possible through an observed linear relationship between the absorbance of vibrations (IRAS) of both phases and the corresponding mass (QCM). The quantification of cuprous oxide was further supported by ex situ coulometric reduction of the corrosion products. The growth rate of cuprous oxide was initially very fast but almost zero after exposure where it reached an average thickness of . Copper acetate exhibited a more constant growth rate. Atomic force microscopy showed a uniform growth of cuprous oxide with surface roughness that increased with time and localized formation of copper acetate. The quantified data are consistent with a previously proposed model that involves proton- and acetate-induced dissolution of copper and subsequent precipitation of cuprous oxide and copper acetate.