Selective and stable CO2 electroreduction at high rates via control of local H2O/CO2 ratio

Chen, Junmei; Qiu, Haoran; Zhao, Yilin; Yang, Haozhou; Fan, Lei; Liu, Zhihe; Xi, ShiBo; Zheng, Guangtai; Chen, Jiayi; Chen, Lei; Liu, Ya; Guo, Liejin; Wang, Lei

doi:10.1038/s41467-024-50269-1

Nat Commun

2024

DOI: 10.1038/s41467-024-50269-1

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Selective and stable CO2 electroreduction at high rates via control of local H2O/CO2 ratio

Junmei Chen,

Haoran Qiu,

Yilin Zhao

et al.

Abstract: Controlling the concentrations of H2O and CO2 at the reaction interface is crucial for achieving efficient electrochemical CO2 reduction. However, precise control of these variables during catalysis remains challenging, and the underlying mechanisms are not fully understood. Herein, guided by a multi-physics model, we demonstrate that tuning the local H2O/CO2 concentrations is achievable by thin polymer coatings on the catalyst surface. Beyond the often-explored hydrophobicity, polymer properties of gas permea… Show more

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Cited by 5 publications

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Preserving Molecular Tuning for Enhanced Electrocatalytic CO₂‐to‐Ethanol Conversion

Fu,

Li,

Chen

et al. 2024

Angewandte Chemie

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Modifying catalyst surface with small molecular‐additives presents a promising avenue for enhancing electrocatalytic performance. However, challenges arise in preserving the molecular‐additives and maximizing their tuning effect, particularly at high current‐densities. Herein, we develop an effective strategy to preserve the molecular‐additives on electrode surface by applying a thin protective layer. Taking 4‐dimethylaminopyridine (DMAP) as an example of a molecular‐additive, the hydrophobic protection layer on top of the DMAP‐functionalized Cu‐catalyst effectively prevents its leaching during CO2 electroreduction (CO2R). Consequently, the confined DMAP molecules substantially promote the CO2‐to‐multicarbon conversion at low overpotentials. For instance, at a potential as low as ‐0.47 V vs. reversible hydrogen electrode, the DMAP‐functionalized Cu exhibits over 80% selectivity towards multi‐carbon products, while the pristine Cu shows only ~35% selectivity for multi‐carbon products. Notably, ethanol appears as the primary product on DMAP‐functionalized Cu, with selectivity approaching 50% at a high current density of 400 mA cm−2. Detailed kinetic analysis, in‐situ spectroscopies, and theoretical calculations indicate that DMAP‐induced electron accumulations on surface Cu‐sites decrease the reaction energy for C‐C coupling. Additionally, the interactions between DMAP and oxygenated intermediates facilitate the ethanol formation pathway in CO2R. Overall, this study showcases an effective strategy to guide future endeavors involving molecular tuning effects.

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Preserving Molecular Tuning for Enhanced Electrocatalytic CO₂‐to‐Ethanol Conversion

Fu,

Li,

Chen

et al. 2024

Angewandte Chemie

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Preserving Molecular Tuning for Enhanced Electrocatalytic CO₂‐to‐Ethanol Conversion

Fu,

Li,

Chen

et al. 2024

Angew Chem Int Ed

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Understanding and Tuning the Effects of H₂O on Catalytic CO and CO₂ Hydrogenation

Wang,

Zhang,

Wang

et al. 2024

Chem. Rev.

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Catalytic CO x (CO and CO 2 ) hydrogenation to valued chemicals is one of the promising approaches to address challenges in energy, environment, and climate change. H 2 O is an inevitable side product in these reactions, where its existence and effect are often ignored. In fact, H 2 O significantly influences the catalytic active centers, reaction mechanism, and catalytic performance, preventing us from a definitive and deep understanding on the structure-performance relationship of the authentic catalysts. It is necessary, although challenging, to clarify its effect and provide practical strategies to tune the concentration and distribution of H 2 O to optimize its influence. In this review, we focus on how H 2 O in CO x hydrogenation induces the structural evolution of catalysts and assists in the catalytic processes, as well as efforts to understand the underlying mechanism. We summarize and discuss some representative tuning strategies for realizing the rapid removal or local enrichment of H 2 O around the catalysts, along with brief techno-economic analysis and life cycle assessment. These fundamental understandings and strategies are further extended to the reactions of CO and CO 2 reduction under an external field (light, electricity, and plasma). We also present suggestions and prospects for deciphering and controlling the effect of H 2 O in practical applications.

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Selective and stable CO2 electroreduction at high rates via control of local H2O/CO2 ratio

Cited by 5 publications

References 77 publications

Preserving Molecular Tuning for Enhanced Electrocatalytic CO₂‐to‐Ethanol Conversion

Preserving Molecular Tuning for Enhanced Electrocatalytic CO₂‐to‐Ethanol Conversion

Preserving Molecular Tuning for Enhanced Electrocatalytic CO₂‐to‐Ethanol Conversion

Understanding and Tuning the Effects of H₂O on Catalytic CO and CO₂ Hydrogenation

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Selective and stable CO2 electroreduction at high rates via control of local H2O/CO2 ratio

Cited by 5 publications

References 77 publications

Preserving Molecular Tuning for Enhanced Electrocatalytic CO2‐to‐Ethanol Conversion

Preserving Molecular Tuning for Enhanced Electrocatalytic CO2‐to‐Ethanol Conversion

Preserving Molecular Tuning for Enhanced Electrocatalytic CO2‐to‐Ethanol Conversion

Understanding and Tuning the Effects of H2O on Catalytic CO and CO2 Hydrogenation

Contact Info

Product

Resources

About

Preserving Molecular Tuning for Enhanced Electrocatalytic CO₂‐to‐Ethanol Conversion

Preserving Molecular Tuning for Enhanced Electrocatalytic CO₂‐to‐Ethanol Conversion

Preserving Molecular Tuning for Enhanced Electrocatalytic CO₂‐to‐Ethanol Conversion

Understanding and Tuning the Effects of H₂O on Catalytic CO and CO₂ Hydrogenation