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能源与环境催化中场效应的视角。

A perspective on field-effect in energy and environmental catalysis.

作者信息

Li HuangJingWei, Li Hongmei, Du Mengzhen, Zhou Erjun, Leow Wan Ru, Liu Min

机构信息

Hunan Joint International Research Center for Carbon Dioxide Resource Utilization, State Key Laboratory of Powder Metallurgy, School of Physics, Central South University Changsha 410083 P. R. China

Institute of Sustainability for Chemicals, Energy and Environment (ISCE2), Agency for Science, Technology and Research (A*STAR) Singapore 627833 Singapore.

出版信息

Chem Sci. 2024 Dec 18;16(4):1506-1527. doi: 10.1039/d4sc07740g. eCollection 2025 Jan 22.

DOI:10.1039/d4sc07740g
PMID:39759941
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC11694487/
Abstract

The development of catalytic technologies for sustainable energy conversion is a critical step toward addressing fossil fuel depletion and associated environmental challenges. High-efficiency catalysts are fundamental to advancing these technologies. Recently, field-effect facilitated catalytic processes have emerged as a promising approach in energy and environmental applications, including water splitting, CO reduction, nitrogen reduction, organic electrosynthesis, and biomass recycling. Field-effect catalysis offers multiple advantages, such as enhancing localized reactant concentration, facilitating mass transfer, improving reactant adsorption, modifying electronic excitation and work functions, and enabling efficient charge transfer and separation. This review begins by defining and classifying field effects in catalysis, followed by an in-depth discussion on their roles and potential to guide further exploration of field-effect catalysis. To elucidate the theory-structure-activity relationship, we explore corresponding reaction mechanisms, modification strategies, and catalytic properties, highlighting their relevance to sustainable energy and environmental catalysis applications. Lastly, we offer perspectives on potential challenges that field-effect catalysis may face, aiming to provide a comprehensive understanding and future direction for this emerging area.

摘要

开发用于可持续能源转换的催化技术是应对化石燃料枯竭及相关环境挑战的关键一步。高效催化剂是推动这些技术发展的基础。近来,场效应促进的催化过程已成为能源和环境应用中的一种有前景的方法,包括水分解、CO还原、氮还原、有机电合成和生物质循环利用。场效应催化具有多种优势,例如提高局部反应物浓度、促进传质、改善反应物吸附、改变电子激发和功函数,以及实现高效的电荷转移和分离。本综述首先对催化中的场效应进行定义和分类,随后深入讨论它们在指导场效应催化进一步探索方面的作用和潜力。为阐明理论 - 结构 - 活性关系,我们探究相应的反应机理、改性策略和催化性能,突出它们与可持续能源和环境催化应用的相关性。最后,我们对场效应催化可能面临的潜在挑战提出观点,旨在为这一新兴领域提供全面的理解和未来方向。

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