Abstract

Air pollutants such as carbon dioxide play an important role in atmospheric corrosion processes and therefore in the degradation reactions occurring on metal surfaces exposed to an ambient atmosphere. It is known from macroscopic studies that ultraviolet (UV) light influences these surface reactions with respect to the reaction rate and the product for- mation itself even though the exact mechanisms have not been elucidated in situ at a sub-� m level so far. Therefore, the role of CO2 in the humidified ambient atmosphere and the influence of UV light on the initial atmospheric corrosion be- haviour of silver surfaces were investigated under in situ conditions using a combined InfraRed Reflection Absorption Spectroscopy (IRRAS) and Quartz Crystal Microbalance (QCM) set-up. To obtain 3-dimensional information about the depth distribution of the corrosion products formed, ex situ Time of Flight Secondary Ion Mass Spectrometry (TOF- SIMS) measurements were performed additionally. The investigations revealed in situ the main and intermediate reaction products during the formation of basic silver carbonate on a polycrystalline silver surface. Furthermore, a strong depend- ency of the product formation rate with respect to the CO2 concentration and the humidity content in the ambient atmos- phere as well as the influence of UV light irradiation of the surface could be demonstrated.