Collaborative hydrothermal and calcination fabrication of ZnOS heterostructures for visible-light-driven H 2 production

Collaborative hydrothermal and calcination fabrication of ZnOS heterostructures for visible-light-driven H 2 production

Photocatalytic water splitting is forecasted as a promising strategy for H production. In this work, novel zinc oxide/zinc sulfide (ZnOS- ) ( = 1, 2, 3 and 4) heterostructures were fabricated by a collaborative hydrothermal and calcination method with different amounts of trithiocyanuric acid. The f...

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Veröffentlicht in:Physical chemistry chemical physics : PCCP 2023-02, Vol.25 (5), p.3617-3621
Hauptverfasser: Chen, XueLi, Lin, ChenXiang, Lai, LanHai, Liu, MingRui, Zheng, Kai, Li, SongTao, Li, HaiTao
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container_issue 5
container_start_page 3617
container_title Physical chemistry chemical physics : PCCP
container_volume 25
creator Chen, XueLi
Lin, ChenXiang
Lai, LanHai
Liu, MingRui
Zheng, Kai
Li, SongTao
Li, HaiTao
description Photocatalytic water splitting is forecasted as a promising strategy for H production. In this work, novel zinc oxide/zinc sulfide (ZnOS- ) ( = 1, 2, 3 and 4) heterostructures were fabricated by a collaborative hydrothermal and calcination method with different amounts of trithiocyanuric acid. The formation of ZnOS- heterostructures was confirmed by PXRD, XPS, and HRTEM. Moreover, ZnOS-3 nanoparticles exhibited homogeneous and smooth surface morphology structure. ZnOS-3 displayed efficient charge separation and transfer efficiency upon photoinduction. ZnOS-3 showed the highest average H evolution reaction rate (78.87 μmol h ) under visible-light irradiation, which increased with increase in the ratio of trithiocyanuric acid in the ZnOS- series. This work provides a new insight to prepare uniformly integrated heterostructures of metal oxides/sulfides for visible-light-driven H generation.
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In this work, novel zinc oxide/zinc sulfide (ZnOS- ) ( = 1, 2, 3 and 4) heterostructures were fabricated by a collaborative hydrothermal and calcination method with different amounts of trithiocyanuric acid. The formation of ZnOS- heterostructures was confirmed by PXRD, XPS, and HRTEM. Moreover, ZnOS-3 nanoparticles exhibited homogeneous and smooth surface morphology structure. ZnOS-3 displayed efficient charge separation and transfer efficiency upon photoinduction. ZnOS-3 showed the highest average H evolution reaction rate (78.87 μmol h ) under visible-light irradiation, which increased with increase in the ratio of trithiocyanuric acid in the ZnOS- series. 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title Collaborative hydrothermal and calcination fabrication of ZnOS heterostructures for visible-light-driven H 2 production
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