Atomic Design of Copper Active Sites in Pristine Metal–Organic Coordination Compounds for Electrocatalytic Carbon Dioxide Reduction

Wang, Juan; Wa, Qingbo; Diao, Qi; Liu, Fu; Hao, Fengkun; Xiong, Yuecheng; Wang, Yunhao; Zhou, Jingwen; Meng, Xiang; Guo, Liang; Fan, Zhanxi

doi:10.1002/smtd.202400432

Small Methods

2024

DOI: 10.1002/smtd.202400432

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Atomic Design of Copper Active Sites in Pristine Metal–Organic Coordination Compounds for Electrocatalytic Carbon Dioxide Reduction

Juan Wang,

Qingbo Wa,

Qi Diao

et al.

Abstract: Electrocatalytic carbon dioxide reduction reaction (CO2RR) has emerged as a promising and sustainable approach to cut carbon emissions by converting greenhouse gas CO2 to value‐added chemicals and fuels. Metal–organic coordination compounds, especially the copper (Cu)‐based coordination compounds, which feature well‐defined crystalline structures and designable metal active sites, have attracted much research attention in electrocatalytic CO2RR. Herein, the recent advances of electrochemical CO2RR on pristine … Show more

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Constructing Asymmetric Cu Catalytic Sites for CO₂ Electroreduction with Higher Selectivity to C₂ Products

Meng,

Yao,

et al. 2024

ChemSusChem

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The design of catalytic sites with tunable properties is considered a promising approach to advance the reduction of CO2 into valuable fuels and chemicals, as well as to achieve carbon neutrality. However, significant challenges remain in precisely constructing catalytic sites to adjust target reduction products. In this study, catalysts were derived from metal‐organic frameworks (MOFs) with different coordination environments during the electrochemical CO2 reduction reaction (eCO2RR), referred to as Cu‐N2O2 and Cu‐N2O3, respectively. Higher selectivity towards the production of C2 products was exhibited by the Cu‐N2O2‐derived catalysts, characterized by asymmetric catalytic centers of Cu0 and Cu+, compared to the Cu‐N2O3‐derived catalysts, which contained only symmetric catalytic centers of Cu0 sites. This enhanced selectivity is attributed to the synergistic interaction between the Cu0 and Cu+ sites, facilitating the multi‐electron transfer process and improving the activation of CO2. This study explores how the coordination environment affects the catalytic performance of catalysts derived from MOFs, providing valuable insights for the development of more effective catalysts aimed at CO2 reduction.

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Constructing Asymmetric Cu Catalytic Sites for CO₂ Electroreduction with Higher Selectivity to C₂ Products

Meng,

Yao,

et al. 2024

ChemSusChem

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Metal–Organic Frameworks-Based Catalysts for Methane Production

Xu,

Zhang,

et al. 2024

Ind. Eng. Chem. Res.

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Methane is important as an electrofuel (e-fuel), which can be efficiently converted into cleaner energy sources, thereby reducing carbon emissions and supporting the transition to sustainable energy. Because of their specific properties, metal−organic framework (MOF)-based catalysts have drawn significant attention to methane production, such as high surface area, multiple active sites, tunability, versatility, and porosity. With the growing progresses on MOFs and their catalytic behavior for methane production, this review focuses on how to enhance the performance of MOF-based catalysts through multicomponent design and stability improvements. It addresses the challenges faced in methane production using MOF-based catalysts and highlights the critical requirements for practical applications. The review summarizes strategies for designing catalysts with specific multicomponent features by using MOFs as precursors to construct multimetallic MOFs, single-atom MOF catalysts, and functional MOF composites. Moreover, recent advances in MOF-based catalysts, including their coordination structures and compositions for methane production and improved stability, are discussed. The review also provides an overview of the application of MOF-based catalysts in methane production, covering areas such as photocatalysis, electroreduction, and biomethane production. Finally, it outlines the challenges and suggests the future directions for the practical application of MOF-based catalysts in methane production.

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Metal Cluster-based Crystalline Materials for the Electrocatalytic Reduction of Carbon Dioxide

Meng,

Dong,

et al. 2024

ACS Materials Lett.

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Atomic Design of Copper Active Sites in Pristine Metal–Organic Coordination Compounds for Electrocatalytic Carbon Dioxide Reduction

Cited by 3 publications

References 163 publications

Constructing Asymmetric Cu Catalytic Sites for CO₂ Electroreduction with Higher Selectivity to C₂ Products

Constructing Asymmetric Cu Catalytic Sites for CO₂ Electroreduction with Higher Selectivity to C₂ Products

Metal–Organic Frameworks-Based Catalysts for Methane Production

Metal Cluster-based Crystalline Materials for the Electrocatalytic Reduction of Carbon Dioxide

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Atomic Design of Copper Active Sites in Pristine Metal–Organic Coordination Compounds for Electrocatalytic Carbon Dioxide Reduction

Cited by 3 publications

References 163 publications

Constructing Asymmetric Cu Catalytic Sites for CO2 Electroreduction with Higher Selectivity to C2 Products

Constructing Asymmetric Cu Catalytic Sites for CO2 Electroreduction with Higher Selectivity to C2 Products

Metal–Organic Frameworks-Based Catalysts for Methane Production

Metal Cluster-based Crystalline Materials for the Electrocatalytic Reduction of Carbon Dioxide

Contact Info

Product

Resources

About

Constructing Asymmetric Cu Catalytic Sites for CO₂ Electroreduction with Higher Selectivity to C₂ Products

Constructing Asymmetric Cu Catalytic Sites for CO₂ Electroreduction with Higher Selectivity to C₂ Products