催化作用
烯烃纤维
甲酸
化学
甲醇
纳米技术
工作(物理)
材料科学
组合化学
碳纤维
反应条件
氧气
作者
Baichuan Zhou,Yang Xu,Danyang Li,Huacheng Yang,Haifeng Qi,Qinghua Liu
标识
DOI:10.1021/acscatal.6c00307
摘要
High Resolution Image Download MS PowerPoint Slide The catalytic hydrogenation of CO 2 offers a promising route for carbon utilization but remains fundamentally constrained by the inertness of CO 2 and the complexity of competing reaction pathways. High-entropy alloys and high-entropy oxides, composed of five or more principal elements stabilized by configurational entropy, have recently emerged as a transformative platform for addressing these challenges. This Review provides a critical and focused overview of entropy-driven catalyst design for CO 2 hydrogenation, including CO formation via reverse water−gas shift, methanation, methanol synthesis, C 2 + olefin production, and formic acid generation. Emphasis is placed on synthetic strategies enabling atomic-level mixing, mechanistic insights into multi-site cooperation, dynamic exsolution-dissolution behavior, and the roles of lattice distortion, oxygen vacancies, and strong metal−support interactions in regulating activity and selectivity. By integrating experimental advances with emerging structure−function relationships, this work delineates the opportunities, limitations, and future directions of high-entropy catalysts as adaptive systems for efficient and durable CO 2 valorization.
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