Rui Ren , Sitan Li , Yulan Gu , Guifen Li , Dongdong Xue , Nuo Liu , Yali Zhang , Li An , Jiangwei Zhang
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引用次数: 0
Abstract
The challenges posed by environmental pollution, global warming resulting from carbon dioxide emissions, and energy scarcity jeopardize the sustainable progress of humanity. Prioritizing the advancement and sustainability of renewable energy sources is imperative to bolster global efforts promoting the displacement of fossil fuels and attaining carbon neutrality. Diverse material categories have been explored, encompassing potential applications in nitrogen reduction reactions, carbon dioxide reduction, water electrolysis, biomass conversion, and battery catalysis. These materials have undergone refinement through techniques like alloy synthesis, introduction of defects/dopants, and construction of heterostructures, resulting in significant enhancements. While many catalysts have demonstrated excellent catalytic performance in reactions such as nitrogen reduction, carbon dioxide reduction, water splitting, and biomass conversion, numerous questions regarding catalyst structure, active site functionality, and catalytic mechanisms remain unanswered. In this review, we summarize the progress of nanomaterials in energy catalytic conversion (The process where catalytic nanomaterials facilitate the conversion of energy carriers or small molecules into valuable products) of small molecules over the past five years, and systematically illustrate the characterization of nanomaterials in chemical reactions by X-ray absorption spectroscopy (XAS). Utilizing XAS technology to identify the active components of catalysts, track the dynamic structural evolution of catalysts, and observe stable reaction intermediates in transition metal single-atom catalysts, transition metal oxides, and metal polycrystals. XAS shows promising potential in various fields such as carbon reduction, nitrogen reduction, biomass conversion and porous materials, garnering widespread recognition in the catalysis community.
环境污染、二氧化碳排放导致的全球变暖以及能源匮乏带来的挑战危及人类的可持续发展。优先考虑可再生能源的进步和可持续发展,是推动全球努力取代化石燃料和实现碳中和的当务之急。目前已探索出多种材料类别,包括氮还原反应、二氧化碳还原、水电解、生物质转化和电池催化等方面的潜在应用。通过合金合成、引入缺陷/掺杂剂和构建异质结构等技术对这些材料进行了改进,使其性能显著提高。虽然许多催化剂在氮还原、二氧化碳还原、水分离和生物质转化等反应中表现出了卓越的催化性能,但有关催化剂结构、活性位点功能和催化机理的许多问题仍未得到解答。在这篇综述中,我们总结了过去五年来纳米材料在小分子能量催化转化(催化纳米材料促进能量载体或小分子转化为有价值产品的过程)方面的研究进展,并通过 X 射线吸收光谱(XAS)系统阐述了纳米材料在化学反应中的表征。利用 XAS 技术鉴定催化剂的活性成分,跟踪催化剂的动态结构演变,观察过渡金属单原子催化剂、过渡金属氧化物和金属多晶体中稳定的反应中间体。XAS 在碳还原、氮还原、生物质转化和多孔材料等多个领域显示出巨大的潜力,获得了催化界的广泛认可。
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