Insights on forming N,O-coordinated Cu single-atom catalysts for electrochemical reduction CO2 to methane

Insights on forming N,O-coordinated Cu single-atom catalysts for electrochemical reduction CO2 to methane

Single-atom catalysts (SACs) are promising candidates to catalyze electrochemical CO 2 reduction (ECR) due to maximized atomic utilization. However, products are usually limited to CO instead of hydrocarbons or oxygenates due to unfavorable high energy barrier for further electron transfer on synthe...

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Bibliographic Details
Published in:Nature communications Vol. 12; no. 1; p. 586
Main Authors: Cai, Yanming, Fu, Jiaju, Zhou, Yang, Chang, Yu-Chung, Min, Qianhao, Zhu, Jun-Jie, Lin, Yuehe, Zhu, Wenlei
Format: Journal Article
Language:English
Published: London Nature Publishing Group UK 26-01-2021
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Subjects:
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Active sites
Aqueous electrolytes
Carbon dioxide
Catalysts
Chemical reduction
Chemical synthesis
Electrochemistry
Electron transfer
Electronic structure
Energy
Humanities and Social Sciences
Hydrocarbons
Intermediates
Low temperature
Methane
multidisciplinary
Science
Science (multidisciplinary)
Selectivity
Single atom catalysts
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Summary:Single-atom catalysts (SACs) are promising candidates to catalyze electrochemical CO 2 reduction (ECR) due to maximized atomic utilization. However, products are usually limited to CO instead of hydrocarbons or oxygenates due to unfavorable high energy barrier for further electron transfer on synthesized single atom catalytic sites. Here we report a novel partial-carbonization strategy to modify the electronic structures of center atoms on SACs for lowering the overall endothermic energy of key intermediates. A carbon-dots-based SAC margined with unique CuN 2 O 2 sites was synthesized for the first time. The introduction of oxygen ligands brings remarkably high Faradaic efficiency (78%) and selectivity (99% of ECR products) for electrochemical converting CO 2 to CH 4 with current density of 40 mA·cm -2 in aqueous electrolytes, surpassing most reported SACs which stop at two-electron reduction. Theoretical calculations further revealed that the high selectivity and activity on CuN 2 O 2 active sites are due to the proper elevated CH 4 and H 2 energy barrier and fine-tuned electronic structure of Cu active sites. Single-atom catalysts (SACs) are promising candidates to catalyze CO 2 reduction for the formation of high value hydrocarbons but most of the reactions yield CO. Here, the authors show a low-temperature calcining process to fabricate a carbon-dots-based SAC to efficiently convert CO 2 to methane.
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ISSN:2041-1723
2041-1723
DOI:10.1038/s41467-020-20769-x