Photo-assisted thermal catalytic Fischer-Tropsch synthesis over Co-Cu/CeO2

In this work, a photo-assisted thermal catalytic Fischer-Tropsch reaction over bimetallic Co-Cu/CeO2 was constructed. It was found that alcohols can be produced under 3 MPa at 180 degrees C in the dark. Under light irradiation, the yield of alcohol increased 1.5 times, and the selectivity was maintained at the same temperature. Based on the XPS results, in situ H-2-pulse chemisorption and in situ diffuse reflection infrared Fourier transform spectroscopy (DRIFTS), it is proposed that Co as an active site can adsorb CO catalysing hydrogenation reactions to produce alcohols. Under the irradiation, CeO2 generates photo-generated electrons and transfers them to Co, so that the electron-rich density of Co facilitates the adsorption and activation of CO. Moreover, the light also induces Cu to produce localized surface plasmon resonance (LSPR) and excite hot electrons, which promotes the dissociation of H-2 and the regeneration of oxygen vacancies on the CeO2 surface. Both light-induced behaviors promote the Fischer-Tropsch reaction.

Automated summary

In this study, a photo-assisted thermal catalytic Fischer-Tropsch reaction over bimetallic Co-Cu/CeO2 was investigated. It was observed that alcohols could be produced under 3 MPa at 180 degrees C in the absence of light. With light irradiation, the yield of alcohol increased by 1.5 times while maintaining the selectivity at the same temperature. The research suggested that Co acted as the active site for CO adsorption and catalyzed hydrogenation reactions to produce alcohols. Under irradiation, CeO2 generated photo-generated electrons that were transferred to Co, enhancing the electron-rich density and facilitating the adsorption and activation of CO. Furthermore, the light induced Cu to produce localized surface plasmon resonance (LSPR) and excite hot electrons, promoting the dissociation of H-2 and the regeneration of oxygen vacancies on the CeO2 surface. Both light-induced behaviors contributed to the enhancement of the Fischer-Tropsch reaction.