Single-Atomic Cu with Multiple Oxygen Vacancies on Ceria for Electrocatalytic CO<sub>2</sub> Reduction to CH<sub>4</sub>

Wang, Yifei; Chen, Zheng; Han, Peng; Du, Yonghua; Gu, Zhengxiang; Xu, Xin; Zheng, Gengfeng

doi:10.1021/acscatal.8b01014

Cited by 495 publications

(411 citation statements)

References 42 publications

(74 reference statements)

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“…Ethylene (C 2 H 4 ), an important raw material, is one of the main C2 products over Cu electrodes . However, due to the simultaneous production of H 2 and other C1 species (i.e., CO, CH 4 ), the Faradaic efficiency for the production of C 2 H 4 (FE C2H4 ) on metallic Cu is usually low . Efforts to improve the FE C2H4 of Cu‐based catalysts have focused on optimizing the sizes, morphologies, and exposed crystal facets of metallic Cu NPs .…”

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confidence: 99%

Cu₂O Nanoparticles with Both {100} and {111} Facets for Enhancing the Selectivity and Activity of CO₂ Electroreduction to Ethylene

et al. 2020

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Cu2O nanoparticles (NPs) enclosed with different crystal facets, namely, c‐Cu2O NPs with {100} facets, o‐Cu2O NPs with {111} facets, and t‐Cu2O NPs with both {111} and {100} facets, are prepared and their electrocatalytic properties for the reduction of CO2 to C2H4 are evaluated. It is shown that the selectivity and activity of the C2H4 production depend strongly on the crystal facets exposed in Cu2O NPs. The selectivities for the C2H4 production increases in the order, c‐Cu2O < o‐Cu2O < t‐Cu2O, (with FEC2H4 = 38%, 45%, and 59%, respectively). This study suggests that Cu2O NPs are more likely responsible for the selectivity and activity for the C2H4 production than the metallic Cu NPs produced on the surface of Cu2O NPs. This work provides a new route for enhancing the selectivity of the electrocatalytic CO2 reduction by crystal facet engineering.

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Cu₂O Nanoparticles with Both {100} and {111} Facets for Enhancing the Selectivity and Activity of CO₂ Electroreduction to Ethylene

et al. 2020

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“…Wang et al proposed the design of multiple oxygen vacancies formation by doping single atomic Cu metal (4% doping level) into Ce nanorods to optimize CO 2 RR to CH 4 , attaining a FE CH4 of 58% at −1.8 V with good stability ( Figure 11 ). Moreover, as indicated in Figure , variation in Cu doping level can alter the product selectivity of CO 2 RR. Moreover, theoretical DFT calculations further confirmed that three‐oxygen vacancies bound Cu structure could efficiently activate CO 2 and convert it to CH 4 (Figure c–g).…”

Section: Active Sites In Metal‐based Catalystsmentioning

confidence: 92%

“…Data from refs. . The detailed catalytic activity of these catalysts is presented in Table S3 (Supporting Information).…”

Section: Active Sites In Metal‐based Catalystsmentioning

confidence: 99%

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A Disquisition on the Active Sites of Heterogeneous Catalysts for Electrochemical Reduction of CO₂ to Value‐Added Chemicals and Fuel

Daiyan

Saputera

Masood

et al. 2020

Advanced Energy Materials

120

102

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Renewable‐electricity‐powered electrocatalytic CO2 reduction reactions (CO2RR) have been identified as an emerging technology to address the issue of rising CO2 emissions in the atmosphere. While the CO2RR has been demonstrated to be technically feasible, further improvements in catalyst performance through active sites engineering are a prerequisite to accelerate its commercial feasibility for utilization in large CO2‐emitting industrial sources. Over the years, the improved understanding of the interaction of CO2 with the active sites has allowed superior catalyst design and subsequent attainment of prominent CO2RR activity in literature. This review tracks the evolution of the understanding of CO2RR active sites on different electrocatalysts such as metals, metal‐oxides, single atoms, metal‐carbon, and subsequently metal‐free carbon‐based catalysts. Despite the tremendous research efforts in the field, many scientific questions on the role of various active sites in governing CO2RR activity, selectivity, stability, and pathways are still unanswered. These gaps in knowledge are highlighted and a discussion is set forth on the merits of utilizing advanced in‐situ and operando characterization techniques and machine learning (ML). Using this technique, the underlying mechanisms can be discerned, and as a result new strategies for designing active sites may be uncovered. Finally, this review advocates an interdisciplinary approach to discover and design CO2RR active sites (rather than focusing merely on catalyst activity) in a bid to stimulate practical research for industrial application.

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“…TiO 2 :Ru with Ti 3+ and Ru 5+ achieved high H 2 evolution reaction activity with appropriate H 2 adsorption Gibbs free energies. In mesoporous CeO 2 nanorods, substitution of single Cu atoms in the CeO 2 (110) surface can stably enrich up to three oxygen vacancies around each Cu site; this phenomenon yields a highly effective catalytic center for CO 2 adsorption and activation …”

Section: Applications Of Nonsimpmsmentioning

confidence: 99%

Nonsiliceous Mesoporous Materials: Design and Applications in Energy Conversion and Storage

Wang

Guo

Luo

et al. 2019

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In this work, the progress in the design of nonsiliceous mesoporous materials (nonSiMPMs) over the last five years from the perspectives of the chemical composition, morphology, loading, and surface modification is summarized. Carbon, metal, and metal oxide are in focus, which are the most promising compositions. Then, representative applications of nonSiMPMs are demonstrated in energy conversion and storage, including recent technical advances in dye‐sensitized solar cells, perovskite solar cells, photocatalysts, electrocatalysts, fuel cells, storage batteries, supercapacitors, and hydrogen storage systems. Finally, the requirements and challenges of the design and application of nonSiMPMs are outlined.

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Single-Atomic Cu with Multiple Oxygen Vacancies on Ceria for Electrocatalytic CO₂ Reduction to CH₄

Cited by 495 publications

References 42 publications

Cu₂O Nanoparticles with Both {100} and {111} Facets for Enhancing the Selectivity and Activity of CO₂ Electroreduction to Ethylene

Cu₂O Nanoparticles with Both {100} and {111} Facets for Enhancing the Selectivity and Activity of CO₂ Electroreduction to Ethylene

A Disquisition on the Active Sites of Heterogeneous Catalysts for Electrochemical Reduction of CO₂ to Value‐Added Chemicals and Fuel

Nonsiliceous Mesoporous Materials: Design and Applications in Energy Conversion and Storage

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Single-Atomic Cu with Multiple Oxygen Vacancies on Ceria for Electrocatalytic CO2 Reduction to CH4

Cited by 495 publications

References 42 publications

Cu2O Nanoparticles with Both {100} and {111} Facets for Enhancing the Selectivity and Activity of CO2 Electroreduction to Ethylene

Cu2O Nanoparticles with Both {100} and {111} Facets for Enhancing the Selectivity and Activity of CO2 Electroreduction to Ethylene

A Disquisition on the Active Sites of Heterogeneous Catalysts for Electrochemical Reduction of CO2 to Value‐Added Chemicals and Fuel

Nonsiliceous Mesoporous Materials: Design and Applications in Energy Conversion and Storage

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Single-Atomic Cu with Multiple Oxygen Vacancies on Ceria for Electrocatalytic CO₂ Reduction to CH₄

Cu₂O Nanoparticles with Both {100} and {111} Facets for Enhancing the Selectivity and Activity of CO₂ Electroreduction to Ethylene

Cu₂O Nanoparticles with Both {100} and {111} Facets for Enhancing the Selectivity and Activity of CO₂ Electroreduction to Ethylene

A Disquisition on the Active Sites of Heterogeneous Catalysts for Electrochemical Reduction of CO₂ to Value‐Added Chemicals and Fuel