Promoting electrocatalytic CO2 methanation using a molecular modifier on Cu surfaces
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Open Access
Type
ArticleAuthor/s
Wang, ChengKong, Xiangdong
Huang, Junming
Yang, Yu
Zheng, Han
Wang, Huijuan
Dai, Suiyang
Zhang, Shuzhen
Liang, Yongxiang
Geng, Zhigang
Li, Fengwang
Zeng, Jie
Abstract
The electroreduction of CO2 to methane using renewable energy is a promising approach to achieving carbon neutrality. At commercially relevant current densities (>200 mA cm−2), methane selectivity is however below 50%. Herein, we reported a benzenethiol-modified Cu nanoparticle ...
See moreThe electroreduction of CO2 to methane using renewable energy is a promising approach to achieving carbon neutrality. At commercially relevant current densities (>200 mA cm−2), methane selectivity is however below 50%. Herein, we reported a benzenethiol-modified Cu nanoparticle catalyst that achieved a methane faradaic efficiency of 54.5% at a partial current density of 383 mA cm−2, 1.9-fold higher than that of Cu nanoparticle controls. In situ vibrational spectroscopy and density functional theory calculations showed that the benzenethiol modulated the electronic structure of the Cu surface to enable a lowered coverage of *CO, favouring the formation of *CHO, a key intermediate embarking on the CH4 pathway, over the competing carbon–carbon coupling, the pathway towards multicarbons.
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See moreThe electroreduction of CO2 to methane using renewable energy is a promising approach to achieving carbon neutrality. At commercially relevant current densities (>200 mA cm−2), methane selectivity is however below 50%. Herein, we reported a benzenethiol-modified Cu nanoparticle catalyst that achieved a methane faradaic efficiency of 54.5% at a partial current density of 383 mA cm−2, 1.9-fold higher than that of Cu nanoparticle controls. In situ vibrational spectroscopy and density functional theory calculations showed that the benzenethiol modulated the electronic structure of the Cu surface to enable a lowered coverage of *CO, favouring the formation of *CHO, a key intermediate embarking on the CH4 pathway, over the competing carbon–carbon coupling, the pathway towards multicarbons.
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Date
2022Source title
Journal of Materials Chemistry AVolume
10Publisher
RSCFunding information
ARC DE200100477Licence
Copyright All Rights ReservedFaculty/School
Faculty of Engineering, School of Chemical and Biomolecular EngineeringShare