Nanoporous Heterojunction Photocatalysts with Engineered Interfacial Sites for Efficient Photocatalytic Nitrogen Fixation

Photocatalytic N2 reduction reaction (PNRR) offers a promising strategy for sustainable production of ammonia (NH3). However, the reported photocatalysts suffer from low efficiency with great room to improve regarding the charge carrier utilization and active site engineering. Herein, a porous and c...

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Bibliographic Details
Published in:Angewandte Chemie International Edition 2024-12, Vol.63 (51), p.e202412340-n/a
Main Authors: Yuan, Ling, Tang, Cheng, Du, Peiyang, Li, Jiaxin, Zhang, Chaoqi, Xi, Yamin, Bi, Yin, Bao, Tong, Du, Aijun, Liu, Chao, Yu, Chengzhong
Format: Article
Language:English
Subjects:
Ammonia
Charge efficiency
Charge transfer
Chemical bonds
Chemical reduction
Chemisorption
Current carriers
Heterojunctions
Hybridization
Hydrogen evolution
Metal-organic frameworks
Metal––organic framework
Nitrogen Fixation
Nitrogenation
Photocatalysis
Photocatalysts
S-scheme heterojunction
Sustainable production
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Summary:Photocatalytic N2 reduction reaction (PNRR) offers a promising strategy for sustainable production of ammonia (NH3). However, the reported photocatalysts suffer from low efficiency with great room to improve regarding the charge carrier utilization and active site engineering. Herein, a porous and chemically bonded heterojunction photocatalyst is developed for efficient PNRR to NH3 production via hybridization of two semiconducting metal—organic frameworks (MOFs), MIL‐125−NH2 (MIL=Material Institute Lavoisier) and Co‐HHTP (HHTP=2,3,6,7,10,11‐hexahydroxytripehenylene). Experimental and theoretical results demonstrate the formation of Ti−O−Co chemical bonds at the interface, which not only serve as atomic pathway for S‐scheme charge transfer, but also provide electron‐deficient Co centers for improving N2 chemisorption/activation capability and restricting competitive hydrogen evolution. Moreover, the nanoporous structure allows the transportation of reactants to the interfacial active sites at heterojunction, enabling the efficient utilization of charge carriers. Consequently, the rationally designed MOF‐based heterojunction exhibits remarkable PNRR performance with an NH3 production rate of 2.1 mmol g−1 h−1, an apparent quantum yield (AQY) value of 16.2 % at 365 nm and a solar‐to‐chemical conversion (SCC) efficiency of 0.28 %, superior to most reported PNRR photocatalysts. Our work provides new insights into the design principles of high‐performance photocatalysts. A nanoporous and chemically bonded S‐Scheme heterojunction photocatalyst is synthesized by hybridization of two semiconducting MOFs, which exhibits excellent performance of photocatalytic nitrogen reduction reaction with an NH3 production rate of 2.1 mmol g−1 h−1, an apparent quantum yield value of 16.2 % at 365 nm and a solar‐to‐chemical conversion efficiency of 0.28 %.
ISSN:1433-7851
1521-3773
1521-3773
DOI:10.1002/anie.202412340