The oxygen evolution reaction (OER) during alkaline water electrolysis is the bottleneck of water splitting. Perovskite materials have been particularly proposed as good and economically reasonable electrocatalysts for the OER, showing promise and advantages with respect to classic metallic electrodes. However, the degradation of perovskites during catalysis limits their service lifetime. Recently, the material BaCo0.98Ti0.02O3-delta:Co3O4 was shown to be electrocatalytically and chemically stable during water electrolysis even under industrially relevant conditions. The lifetime of this perovskite-based system is prolonged by a factor of 10 in comparison to that of Pr0.2Ba0.8CoO3-delta and is comparable to that of industrially applied electrodes. Here we report on the degradation kinetics of several studied by monitoring the oxygen evolution at microelectrodes. A decrease observed, which is related to chemical and/or structural changes at the oxide OER catalysts at room temperature, comparatively in the reaction rate within a maximum of 60 s is surface.