Abstract
The mechanism of the oxidation of methanol on the surface of heat treated CeO2 nanoparticles was studied using diffuse reflectance infrared Fourier transform spectroscopy (DRIFTS). The study was carried out under high vacuum to ensure no interference from unreacted physisorbed methanol and compared to a similar analysis under pseudo-flow conditions. When methanol reacts with the CeO2 surface, it either chemisorbs to a single cerium atom creating monobound (m) methoxy or to two neighboring cerium atoms forming bridged (b) methoxy groups. From the evacuated analysis, formate production depends directly on the presence and transformation of b-methoxy groups. Hydroxyls are found to facilitate the formation of the two surface methoxy groups, react with m-methoxy groups creating additional b-methoxy groups, and enable the transformation of b-methoxy groups to bidentate formate groups. The reaction mechanism is elucidated through the use of temperature dependent peak height analysis of the collected DRIFTS spectra which are correlated to the transforming surface bound species.
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