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Abstract
Spectroscopic methods enabling real-time monitoring of dynamic surface processes are a prerequisite for identifying how a catalyst triggers a chemical reaction. We present an in situ photoluminescence spectroscopy approach for probing the thermo-catalytic 2-propanol oxidation over mesostructured Co3O4 nanowires. Under oxidative conditions, a distinct blue emission at ~420 nm is detected that increases with temperature up to 280 °C, with an intermediate maximum at 150 °C. Catalytic data gained under comparable conditions show that this course of photoluminescence intensity precisely follows the conversion of 2-propanol and the production of acetone. The blue emission is assigned to the radiative recombination of unbound acetone molecules, the n - π* transition of which is selectively excited by a wavelength of 270 nm. These findings open a pathway for studying thermo-catalytic processes via in situ photoluminescence spectroscopy thereby gaining information about the performance of the catalyst and the formation of intermediate products.
Supplementary materials
Title
Supporting Information: Monitoring Catalytic 2-Propanol Oxidation over Co3O4 Nanowires via In Situ Photoluminescence Spectroscopy
Description
Experimental Methods, sample characterization of Co3O4 nanowires by XRD, TEM, nitrogen physisorption and Raman measurements, influence of TPO on Co3O4 surface coverage with OH/ water (examined with PL spectroscopy and gas chromatography), Co3O4 emission behavior under oxidative conditions (with/without 2-propanol), optical absorption of acetone and 2-propanol as liquid and Co3O4 emission in acetone enriched O2/N2 gas flow.
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