Transition metal carbide‐based photocatalysts for artificial photosynthesis

SmartMat Pub Date : 2023-08-10 DOI:10.1002/smm2.1238
K. J. Wong, J. J. Foo, T. J. Siang, Wee‐Jun Ong
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Abstract

Transition metal carbides, including both MXene and non‐MXene metal carbides, have enjoyed a soaring reputation in recent years. Benefitting from their intriguing physical and chemical characteristics, they shine in multifarious research fields and currently, they have emerged as promising nanomaterials for photocatalysis in energy and environmental science. Herein, based on the recent theoretical research and experimental studies, a systematic and comprehensive review of the expeditious advances of metal carbides and their nano‐architectures in the flourishing arena of photocatalysis is presented. The fundamental mechanism involved in photocatalysis with metal carbides serving as semiconductors or cocatalysts is thoroughly discussed. Besides, we highlight the main synthetic strategies of MXene and non‐MXene metal carbides and unravel the structural properties of the as‐obtained metal carbides via different fabrication routes to establish and elucidate their intriguing role in ameliorating photocatalytic activity. Moreover, the state‐of‐the‐art advancements of metal carbides in diverse photocatalytic applications, including hydrogen evolution reaction, oxygen evolution reaction, overall water splitting, and carbon dioxide reduction reaction, are summarized. In particular, insights into the structure–activity relationship of metal carbide in photocatalysis are elucidated. Finally, this review concludes with the ongoing challenges and perspectives on the future directions of metal carbides in the realm of photocatalysis.
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人工光合作用的过渡金属碳化物基光催化剂
过渡金属碳化物,包括MXene和非MXene金属碳化物,近年来享有飞速发展的声誉。由于其独特的物理和化学特性,纳米材料在许多研究领域大出风头,目前,它们已成为能源和环境科学中有前途的光催化纳米材料。本文基于近年来的理论研究和实验研究,系统、全面地综述了金属碳化物及其纳米结构在光催化领域的快速发展。深入讨论了金属碳化物作为半导体或助催化剂进行光催化的基本机理。此外,我们重点介绍了MXene和非MXene金属碳化物的主要合成策略,并通过不同的制备路线揭示了所获得的金属碳化物的结构性质,以建立和阐明它们在改善光催化活性方面的有趣作用。此外,综述了金属碳化物在析氢反应、析氧反应、全水分解和二氧化碳还原反应等不同光催化应用中的最新进展。特别地,阐明了金属碳化物在光催化中的构效关系。最后,对金属碳化物在光催化领域面临的挑战和未来发展方向进行了展望。
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