Photoelectron “Bridge” in Van Der Waals Heterojunction for Enhanced Photocatalytic CO2 Conversion Under Visible Light

Photoelectron “Bridge” in Van Der Waals Heterojunction for Enhanced Photocatalytic CO2 Conversion Under Visible Light

Constructing Van der Waals heterojunction is a crucial strategy to achieve excellent photocatalytic activity. However, in most Van der Waals heterojunctions synthesized by ex situ assembly, electron transfer encounters huge hindrances at the interface between the two components due to the large spac...

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Published in:Advanced materials (Weinheim) Vol. 35; no. 38; p. e2303047
Main Authors: Pir Muhammad Ismail, Ali, Sajjad, Sharafat, Ali, Li, Jiahao, Liu, Min, Dong, Yan, Raziq, Fazal, Fazli Wahid, Li, Guojing, Yuan, Shuhua, Wu, Xiaoqiang, Yi, Jiabao, Jun Song Chen, Wang, Qingyuan, Li, Zhong, Yang, Ye, Xia, Pengfei, Qiao, Liang
Format: Journal Article
Language:English
Published: Weinheim Wiley Subscription Services, Inc 21-09-2023
Subjects:
Carbon dioxide
Catalytic activity
Catalytic converters
Cobalt
Electron transfer
Heterojunctions
Materials science
Photocatalysis
Photoelectrons
Potential barriers
Tungsten disulfide
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Summary:Constructing Van der Waals heterojunction is a crucial strategy to achieve excellent photocatalytic activity. However, in most Van der Waals heterojunctions synthesized by ex situ assembly, electron transfer encounters huge hindrances at the interface between the two components due to the large spacing and potential barrier. Herein, a phosphate‐bridged Van der Waals heterojunction of cobalt phthalocyanine (CoPc)/tungsten disulfide (WS2) bridged by phosphate (xCoPc‐nPO4−‐WS2) is designed and prepared by the traditional wet chemistry method. By introducing a small phosphate molecule into the interface of CoPc and WS2, creates an electron “bridge”, resulting in a compact combination and eliminating the space barrier. Therefore, the phosphate (PO4−) bridge can serve as an efficient electron transfer channel in heterojunction and can efficiently transmit photoelectrons from WS2 to CoPc under excited states. These excited photoelectrons are captured by the catalytic central Co2+ in CoPc and subsequently convert CO2 molecules into CO and CH4 products, achieving 17‐fold enhancement on the 3CoPc‐0.6PO4−‐WS2 sample compared to that of pure WS2. Introducing a small molecule “bridge” to create an electron transfer channel provides a new perspective in designing efficient photocatalysts for photocatalytic CO2 reduction into valuable products.
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ISSN:0935-9648
1521-4095
DOI:10.1002/adma.202303047