Orienting oxygen vacancies for fast catalytic reaction

Abstract

Catalysis is indispensable to chemical processes and relevant to many aspects of modern life. Owing to the intriguing electronic structures and good ionic properties, multivalent transition metal oxides have attracted attention as key catalysts for various energy and environmental applications. Here, we demonstrate that brownmillerite strontium cobaltite (SrCoO2.5) can be a good cathode material for sold oxide fuel cells and rechargeable batteries due to the open oxygen frameworks. When the orientation of oxygen vacancy channels (OVCs) is properly controlled, one can drastically increase the surface oxygen exchange rate approximately up to two orders of magnitude. The improved oxygen reduction kinetics is attributed to a substantial decrease in the thermal activation energy. Importantly, the strong enhancement of crystallographic orientation-dependent oxygen reduction reaction required the creation of neither structural disorders nor chemical doping. Thus, our epitaxial approach can pave a novel pathway to providing precise interpretation of oxygen reduction reactions and to developing oxide-based energy materials.