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Modulating Charge Separation of Oxygen‐Doped Boron Nitride with Isolated Co Atoms for Enhancing CO2‐to‐CO Photoreduction

To alleviate the greenhouse effect and address the related energy crisis, solar‐driven reduction of carbon dioxide (CO2) to value‐added products is considered as a sustainable strategy. However, the insufficient separation and rapid recombination of photogenerated charge carriers during photocatalys...

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Published in:	Advanced materials (Weinheim) 2024-01, Vol.36 (1), p.e2303287-n/a
Main Authors:	Liang, Jianli, Zhang, Huabin, Song, Qianqian, Liu, Zheyang, Xia, Jing, Yan, Binhang, Meng, Xiangmin, Jiang, Zhifeng, Lou, Xiong Wen (David), Lee, Chun‐Sing
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Language:	English
Subjects:	Boron nitride Carbon dioxide Carbon monoxide Catalytic activity CO2 reduction reaction coordination environment Current carriers electron/hole separation Greenhouse effect Materials science Oxygen Photocatalysis Pyrolysis Reaction kinetics Reduction Separation single‐atom catalysts
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creator	Liang, Jianli Zhang, Huabin Song, Qianqian Liu, Zheyang Xia, Jing Yan, Binhang Meng, Xiangmin Jiang, Zhifeng Lou, Xiong Wen (David) Lee, Chun‐Sing
description	To alleviate the greenhouse effect and address the related energy crisis, solar‐driven reduction of carbon dioxide (CO2) to value‐added products is considered as a sustainable strategy. However, the insufficient separation and rapid recombination of photogenerated charge carriers during photocatalysis greatly limit their reduction efficiency and practical application potential. Here, isolated Cobalt (Co) atoms are successfully decorated into oxygen‐doped boron nitride (BN) via an in situ pyrolysis method, achieving greatly improved catalytic activity and selectivity to the carbon monoxide (CO) product. X‐ray absorption fine spectroscopy demonstrates that the isolated Co atoms are stabilized by the O and N atoms with an unsaturated CoO2N1 configuration. Further experimental investigation and theoretical simulations confirm that the decorated Co atoms not only work as the real active center during the CO2 reduction process, but also perform as the electron pump to promote the electron/hole separation and transfer, resulting in greatly accelerated reaction kinetics and improved activity. In addition, the CoO2N1 coordination geometry is favorable to the conversion from CO2 to COOH, which shall be considered as a selectivity‐determining step for the evolution of the CO products. The surface modulation strategy at the atomic level opens a new avenue for regulating the reaction kinetics for photocatalytic CO2 reduction. Isolated Co atoms are successfully anchored on oxygen‐doped boron nitride (Co/BNF) to enhance photocatalytic CO2 reduction performance. The uniformly dispersed Co atoms with a CoO2N1 coordination geometry play an essential role in promoting the separation of photogenerated charge carriers and lowering the reaction energy barriers, thus boosting the activity and selectivity of Co/BNF for photocatalytic CO2 reduction.
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However, the insufficient separation and rapid recombination of photogenerated charge carriers during photocatalysis greatly limit their reduction efficiency and practical application potential. Here, isolated Cobalt (Co) atoms are successfully decorated into oxygen‐doped boron nitride (BN) via an in situ pyrolysis method, achieving greatly improved catalytic activity and selectivity to the carbon monoxide (CO) product. X‐ray absorption fine spectroscopy demonstrates that the isolated Co atoms are stabilized by the O and N atoms with an unsaturated CoO2N1 configuration. Further experimental investigation and theoretical simulations confirm that the decorated Co atoms not only work as the real active center during the CO2 reduction process, but also perform as the electron pump to promote the electron/hole separation and transfer, resulting in greatly accelerated reaction kinetics and improved activity. In addition, the CoO2N1 coordination geometry is favorable to the conversion from CO2 to COOH, which shall be considered as a selectivity‐determining step for the evolution of the CO products. The surface modulation strategy at the atomic level opens a new avenue for regulating the reaction kinetics for photocatalytic CO2 reduction. Isolated Co atoms are successfully anchored on oxygen‐doped boron nitride (Co/BNF) to enhance photocatalytic CO2 reduction performance. 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subjects	Boron nitride Carbon dioxide Carbon monoxide Catalytic activity CO2 reduction reaction coordination environment Current carriers electron/hole separation Greenhouse effect Materials science Oxygen Photocatalysis Pyrolysis Reaction kinetics Reduction Separation single‐atom catalysts
title	Modulating Charge Separation of Oxygen‐Doped Boron Nitride with Isolated Co Atoms for Enhancing CO2‐to‐CO Photoreduction
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