用于二氧化碳光致还原的金属卤化物过氧化物:最新进展与未来展望

EES catalysis Pub Date : 2024-01-06 DOI:10.1039/D3EY00187C
Zhongliang Dong, Bowen Li, Yinlong Zhu and Wanlin Guo
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引用次数: 0

摘要

自工业革命以来,二氧化碳排放无疑已成为人类面临的最大挑战之一。旨在捕获、封存和利用二氧化碳的技术引起了工业界和学术界的广泛关注。将二氧化碳转化为高附加值化学品和燃料的热转化、电转化和光催化转化是最著名的二氧化碳利用途径。其中,二氧化碳的光催化还原(CO2PR)直接利用太阳能作为活化二氧化碳的动力,产生各种产物,包括 CO、CH4 和 C2+ 碳氢化合物。CO2PR 模仿自然界中的光合作用,也被视为 "人工光合作用",被认为是实现碳中和经济的一种可行方法。最近,金属卤化物过氧化物(MHPs)因其灵活的结构和优异的光电子特性,成为 CO2PR 的潜在光催化剂。本综述全面概述了基于 MHP 的 CO2PR 催化剂的最新发展。首先,详细介绍了 MHP 的晶体结构和光电特性,因为这些是决定 CO2PR 催化性能的关键因素。其次,讨论了提高铅基和无铅 MHP 催化 CO2PR 效率的设计策略,包括形态修饰、共催化剂修饰、离子掺杂和晶面修饰。第三,本综述讨论了基于 MHPs 的 CO2PR 对 CH4 和 C2+ 产物的影响,特别强调了为提高特定产物选择性而采用的方法。最后,我们就 CO2PR 目前面临的研究挑战和未来发展方向提出了自己的观点和看法,我们认为这对于实现 CO2PR 的工业化至关重要。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Metal halide perovskites for CO2 photoreduction: recent advances and future perspectives

Metal halide perovskites for CO2 photoreduction: recent advances and future perspectives

CO2 emission has inarguably become one of the greatest challenges ever faced by mankind since industrial revolution. Techniques aiming at capture, storage and utilization of CO2 have attracted tremendous interest from both industry and academia. Thermal, electrical and photo-catalytic conversion of CO2 to value-added chemicals and fuels is the most well-known approach for CO2 utilization. In particular, photocatalytic reduction of CO2 (CO2PR) directly employs solar energy as the driving force to activate CO2, yielding various products including CO, CH4 and C2+ hydrocarbons. CO2PR, which mimics photosynthesis occurring in nature, is also regarded as “artificial photosynthesis” and is believed to be a promising approach toward carbon neutral economy. Recently, metal halide perovskites (MHPs) have emerged as potential photocatalysts for CO2PR, owing to their flexible structures and excellent photoelectronic properties. This review presents a comprehensive overview of state-of-the-art developments in MHP-based catalysts for CO2PR. Firstly, the crystal structures and photoelectric properties of MHPs are reviewed in detail, as they are the key factors determining CO2PR catalytic performance. Secondly, design strategies to promote the catalytic efficiency of CO2PR to CO conversion for both lead-based and lead-free MHPs are discussed, including morphological modifications, co-catalyst modifications, ion doping and crystal plane modifications. Thirdly, this review addresses MHP-based CO2PR to CH4 and C2+ products, with special emphasis on approaches adopted to promote specific product selectivity. Lastly, our perspectives and opinions are given on current research challenges and future directions for CO2PR, which we consider are critical for its industrialization.

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