Unraveling the Origin of Photocatalytic Deactivation in CeO(2)/Nb(2)O(5) Heterostructure Systems during Methanol Oxidation: Insight into the Role of Cerium Species

[Image: see text] The study provides deep insight into the origin of photocatalytic deactivation of Nb(2)O(5) after modification with ceria. Of particular interest was to fully understand the role of ceria species in diminishing the photocatalytic performance of CeO(2)/Nb(2)O(5) heterostructures. For this purpose, ceria was loaded on niobia surfaces by wet impregnation. The as-prepared materials were characterized by powder X-ray diffraction, nitrogen physisorption, UV–visible spectroscopy, X-ray photoelectron spectroscopy, high-resolution transmission electron microscopy, and photoluminescence measurements. Photocatalytic activity of parent metal oxides (i.e., Nb(2)O(5) and CeO(2)) and as-prepared CeO(2)/Nb(2)O(5) heterostructures with different ceria loadings were tested in methanol photooxidation, a model gas-phase reaction. Deep insight into the photocatalytic process provided by operando-IR techniques combined with results of photoluminescence studies revealed that deactivation of CeO(2)/Nb(2)O(5) heterostructures resulted from increased recombination of photo-excited electrons and holes. The main factor contributing to more efficient recombination of the charge carriers in the heterostructures was the ultrafine size of the ceria species. The presence of such highly dispersed ceria species on the niobia surface provided a strong interface between these two semiconductors, enabling efficient charge transfer from Nb(2)O(5) to CeO(2). However, the ceria species supported on niobia exhibited a high defect site concentration, which acted as highly active recombination centers for the photo-induced charge carriers.