Meng Dan scite author profile

The surface electron density significantly affects the photocatalytic efficiency, especially the photocatalytic CO2 reduction reaction, which involves multi-electron participation in the conversion process. Herein, we propose a conceptually different mechanism for surface electron density modulation based on the model of Au anchored CdS. We firstly manipulate the direction of electron transfer by regulating the vacancy types of CdS. When electrons accumulate on vacancies instead of single Au atoms, the adsorption types of CO2 change from physical adsorption to chemical adsorption. More importantly, the surface electron density is manipulated by controlling the size of Au nanostructures. When Au nanoclusters downsize to single Au atoms, the strong hybridization of Au 5d and S 2p orbits accelerates the photo-electrons transfer onto the surface, resulting in more electrons available for CO2 reduction. As a result, the product generation rate of AuSA/Cd1−xS manifests a remarkable at least 113-fold enhancement compared with pristine Cd1−xS.

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Noble-metal-free MnS/In2S3 composite as highly efficient visible light driven photocatalyst for H2 production from H2S

Dan

Zhang

et al. 2017

Applied Catalysis B: Environmental

157

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Enhanced Photoelectrocatalytic Activities for CH₃OH‐to‐HCHO Conversion on Fe₂O₃/MoO₃: Fe‐O‐Mo Covalency Dominates the Intrinsic Activity

et al. 2021

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The catalytic conversion of alcohols under mild conditions is a great challenge because it is constrained by low selectivity and low activity. Herein, we demonstrate a hollow nanotube Fe2O3/MoO3 heterojunction (FeMo‐2) for the photoelectrocatalytic conversion of small‐molecule alcohols. Experimental and theoretical analyses reveal that the optical carrier transfer rate is enhanced by constructing interfacial internal electric fields and Fe‐O‐Mo charge transfer channels. For the formox process, heterojunctions possess superior HCHO‐selective reaction paths and free energy transitions, optimizing the selectivity of HCHO and enhancing the reactivity. FeMo‐2 shows a greatly improved performance compared to single Fe2O3; the photocurrent density of FeMo‐2 reaches 0.66 mA cm−2, which is 3.88 times that of Fe2O3 (0.17 mA cm−2), and the Faraday efficiency of the CH3OH‐to‐HCHO conversion is 95.7 %. This work may deepen our understanding of interfacial charge separation and has potential for the production of HCHO and for conversion reactions of other small‐molecule alcohols at cryogenic temperatures.

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Meng Dan

Modulating electron density of vacancy site by single Au atom for effective CO2 photoreduction

Noble-metal-free MnS/In2S3 composite as highly efficient visible light driven photocatalyst for H2 production from H2S

Enhanced Photoelectrocatalytic Activities for CH₃OH‐to‐HCHO Conversion on Fe₂O₃/MoO₃: Fe‐O‐Mo Covalency Dominates the Intrinsic Activity

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Meng Dan

Modulating electron density of vacancy site by single Au atom for effective CO2 photoreduction

Noble-metal-free MnS/In2S3 composite as highly efficient visible light driven photocatalyst for H2 production from H2S

Enhanced Photoelectrocatalytic Activities for CH3OH‐to‐HCHO Conversion on Fe2O3/MoO3: Fe‐O‐Mo Covalency Dominates the Intrinsic Activity

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Enhanced Photoelectrocatalytic Activities for CH₃OH‐to‐HCHO Conversion on Fe₂O₃/MoO₃: Fe‐O‐Mo Covalency Dominates the Intrinsic Activity