Selective Electrosynthesis of Urea <i>via</i> C−N Coupling: Current Status, Challenges and Future Prospects

Gu, Yaping; Wu, Yurou; Chen, Shanhu; Zhou, Yangyang; Chen, Chen

doi:10.1002/cctc.202301650

ChemCatChem

2024

DOI: 10.1002/cctc.202301650

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Selective Electrosynthesis of Urea via C−N Coupling: Current Status, Challenges and Future Prospects

Yaping Gu,

Yurou Wu,

Shanhu Chen

et al.

Abstract: Selective electrosynthesis of urea from carbon source (CO2) and nitrogen (N2, NO3−, NO2−) source provides a sustainable strategy for production of essential nitrogen‐based fertilizers. The traditional technology of urea synthesis employs two consecutive processes, synthesis of NH3 from N2+H2 and urea from NH3+CO2, which always involves high energy consumption and environmental concerns. By contrast, urea electrosynthesis avoids the above harsh steps and meanwhile has higher atomic economy. Herein, we present a… Show more

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Cited by 5 publications

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Research Progress of Catalysts with Atomic‐Scale Reactive Sites in Urea Electrosynthesis

Lu,

Zhan,

Chen

et al. 2024

ChemCatChem

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Urea (CO(NH2)2) is the main component of nitrogen‐based fertilizers and is widely used in various industries. Until now, urea production is conducted under high‐temperature and high‐pressure conditions, which involves a considerable carbon footprint. Urea electrosynthesis, which is powered by renewable energy‐derived electricity, has emerged as a sustainable single‐step process for urea production. The development of efficient and stable catalysts is the key to improving the efficiency of urea electrosynthesis. In this review, we summarized the research progress and applications of catalysts with atomic‐scale reactive sites in urea electrosynthesis. First, the catalytic mechanisms of urea electrosynthesis from CO2 and various nitrogenous molecules are discussed. Then, typical electrocatalysts such as single‐atom electrocatalysts, dual‐atom electrocatalysts, clusters, atomic dopants, vacancies, and so forth, are discussed. Furthermore, characterization methods for atomic‐scale reactive sites are summarized. Finally, challenges and suggestions for urea electrosynthesis are proposed. We hope this review can provide some inspiration toward the development of catalysts for efficient and sustainable urea electrosynthesis.

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Research Progress of Catalysts with Atomic‐Scale Reactive Sites in Urea Electrosynthesis

Lu,

Zhan,

Chen

et al. 2024

ChemCatChem

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Electrochemical Transformations of Enamines: Recent Advances and Future Perspectives

Li,

Chen

2024

Eur J Org Chem

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Enamines, containing nucleophilic amino groups and activated C=C bonds, are important building blocks, and widely used in the synthesis of heterocycles, natural products, and pharmaceuticals. In recent years, electrosynthesis has gradually developed into a powerful protocol for constructing chemical bonds due to its high economy, environmental friendliness, and mild reaction conditions. This review summarized the recent advances in the electrochemical transformation of enamines, including the construction of heterocyclic compounds, C(sp2)−H bond functionalization of enamines for synthesis of multi‐substituted alkenes, and the functionalization reactions of enamines via C=C double bond cleavage. The reaction conditions and mechanisms were systematically discussed, and the challenges and future directions of this field were included in this review.

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Electrocatalytic Synthesis of Urea: An In‐depth Investigation from Material Modification to Mechanism Analysis

Cao,

Zhao,

et al. 2024

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Industrial urea synthesis production uses NH3 from the Haber‐Bosch method, followed by the reaction of NH3 with CO2, which is an energy‐consuming technique. More thorough evaluations of the electrocatalytic C−N coupling reaction are needed for the urea synthesis development process, catalyst design, and the underlying reaction mechanisms. However, challenges of adsorption and activation of reactant and suppression of side reactions still hinder its development, making the systematic review necessary. This review meticulously outlines the progress in electrochemical urea synthesis by utilizing different nitrogen (NO3−, N2, NO2−, and N2O) and carbon (CO2 and CO) sources. Additionally, it delves into advanced methods in materials design, such as doping, facet engineering, alloying, and vacancy introduction. Furthermore, the existing classes of urea synthesis catalysts are clearly defined, which include 2D nanomaterials, materials with Mott–Schottky structure, materials with artificially frustrated Lewis pairs, single−atom catalysts (SACs), and heteronuclear dual−atom catalysts (HDACs). A comprehensive analysis of the benefits, drawbacks, and latest developments in modern urea detection techniques is discussed. It is aspired that this review will serve as a valuable reference for subsequent designs of highly efficient electrocatalysts and the development of strategies to enhance the performance of electrochemical urea synthesis.

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Selective Electrosynthesis of Urea via C−N Coupling: Current Status, Challenges and Future Prospects

Cited by 5 publications

References 48 publications

Research Progress of Catalysts with Atomic‐Scale Reactive Sites in Urea Electrosynthesis

Research Progress of Catalysts with Atomic‐Scale Reactive Sites in Urea Electrosynthesis

Electrochemical Transformations of Enamines: Recent Advances and Future Perspectives

Electrocatalytic Synthesis of Urea: An In‐depth Investigation from Material Modification to Mechanism Analysis

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