Zirong Shen scite author profile

Semiconducting quantum dots (QDs) engineering is considered as an effective approach to improve the light-harvesting ability of the devices for solar energy converting. Current routes for the construction of QDs from metal–organic frameworks (MOFs) always retain carbon materials to avoid particle aggregations, which could obstruct light harvesting process. Herein, novel ZnCdS QDs without carbon supporting are rationally designed and fabricated by controlled annealing and a sequential sulfidation and ion-exchange procedure by a zeolitic-imidazolate-framework-8 (ZIF-8)-templated method. Notably, the quantum size could be well controlled, and hence provide the ZnCdS QDs material with suitable band matching, strong electron coupling, uniform and abundant active sites, facilitated photoinduced charge kinetics, and shortened charge diffusion distances, which are vital merits for enhancing photocatalytic performance. The photocatalytic H2 production activity of these QDs can be optimized through adjusting the quantum sizes. Under the irradiation of visible-light and noble-metal cocatalyst-free, an optimal H2 production rate of 3.70 mmol h–1 g–1 could be afford without using noble metal cocatalysts, which is superior to those of bulk ZnCdS and most of the reported ZnCdS-based catalysts. The facile and efficient approach for ZnCdS QDs engineering could be extended to design other kinds of highly efficient metal-sulfide QDs in advanced applications.

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Oxygen Vacancy‐Mediated Exciton Effect in Hierarchical BiOBr Enables Dichotomy of Energy Transfer and Electron Transfer in Photocatalysis

Shen

Luo

Chen

et al. 2022

Adv Funct Materials

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Using solar energy through green and simple artificial photosynthesis systems are considered as a promising way to solve the energy and environmental crisis. However, one of the important primary steps of photosynthesis, i.e., energy transfer, is long being ignored especially in inorganic semiconducting systems due to the small exciton binding energies. Herein, the simultaneous interrogation of the charge transfer and energy transfer steps in a photoexcitation process is proposed by utilizing few-layered nanosheet-assembled hierarchical BiOBr nanotubes with rich oxygen vacancies (OVs) as efficient multifunctional photocatalysts. Benefiting from the integrated 1D/2D structure and abundant OV defects, the excitonic effect strikes a delicate balance in the optimized BiOBr photocatalyst, showing not only improved charge carrier separation and transfer but also enhanced exciton generation. As a result, the hierarchical BiOBr nanotubes exhibit high efficiency toward photocatalytic CO 2 reduction with an impressive CO evolution rate of 135.6 µmol g −1 h −1 without cocatalyst or photosensitizer. The dominant reactive oxygen species of singlet oxygen ( 1 O 2 ) are discriminated for the first time, which originated from an energy transfer process, with electrophilic character, whereas the minor effect of superoxide anion radical ( • O 2 −) with a nucleophilic rate-determining step in the photocatalytic aerobic oxidation of sulfides.

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Efficient hydrogenation of furfural to fufuryl alcohol over hierarchical MOF immobilized metal catalysts

et al. 2021

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Phase segregation via etching-induced cation migration in CoS_x–ZnS nanoarchitectures for solar hydrogen evolution

Shen

Huang

Chen

et al. 2022

Catal. Sci. Technol.

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Zirong Shen

Fabricating sandwich-shelled ZnCdS/ZnO/ZnCdS dodecahedral cages with “one stone” as Z-scheme photocatalysts for highly efficient hydrogen production

Novel ZnCdS Quantum Dots Engineering for Enhanced Visible-Light-Driven Hydrogen Evolution

Oxygen Vacancy‐Mediated Exciton Effect in Hierarchical BiOBr Enables Dichotomy of Energy Transfer and Electron Transfer in Photocatalysis

Efficient hydrogenation of furfural to fufuryl alcohol over hierarchical MOF immobilized metal catalysts

Phase segregation via etching-induced cation migration in CoS_x–ZnS nanoarchitectures for solar hydrogen evolution

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Zirong Shen

Fabricating sandwich-shelled ZnCdS/ZnO/ZnCdS dodecahedral cages with “one stone” as Z-scheme photocatalysts for highly efficient hydrogen production

Novel ZnCdS Quantum Dots Engineering for Enhanced Visible-Light-Driven Hydrogen Evolution

Oxygen Vacancy‐Mediated Exciton Effect in Hierarchical BiOBr Enables Dichotomy of Energy Transfer and Electron Transfer in Photocatalysis

Efficient hydrogenation of furfural to fufuryl alcohol over hierarchical MOF immobilized metal catalysts

Phase segregation via etching-induced cation migration in CoSx–ZnS nanoarchitectures for solar hydrogen evolution

Contact Info

Product

Resources

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Phase segregation via etching-induced cation migration in CoS_x–ZnS nanoarchitectures for solar hydrogen evolution