Yiming He , Fabian H. Müller , Regina Palkovits , Feng Zeng , Chalachew Mebrahtu
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Nevertheless, controlling catalysts at the nanoscale poses challenges, hindering the design of efficient multi-site catalysts. An alternative approach worth considering is to perform a tandem of multiple well-established catalytic reactions (e.g., </span>methanol synthesis, CO</span><sub>2</sub><span>-Fischer-Tropsch-Synthesis, RWGS<span>, syngas conversion, olefin hydration, etc.) to indirectly achieve the conversion of CO</span></span><sub>2</sub> into higher alcohols, instead of direct CO<sub>2</sub> hydrogenation. Therefore, in this review, these alternative strategies of higher alcohols synthesis are discussed, and their potential is evaluated. First, thermodynamic analysis, the selective adjustment strategies, and the current challenges faced for direct CO<sub>2</sub> hydrogenation are introduced. Then, physical integration of multiple catalysts as a feasible strategy to endow the catalyst with multifunctional properties is discussed. 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引用次数: 0
摘要
近年来,由于二氧化碳的大量排放,全球变暖日益严重,因此迫切需要开发减少温室气体二氧化碳排放的技术。将二氧化碳转化为高级醇类是一种前景广阔的工艺,因为它不仅能生产有价值的化学品,还能利用二氧化碳作为原料。目前,大多数报道的催化方法都是基于直接氢化 CO2 来合成高级醇。然而,高级醇的合成涉及多个步骤,需要具有多个功能位点的催化剂,而催化剂之间的协同作用至关重要。然而,在纳米尺度上控制催化剂是一项挑战,阻碍了高效多位点催化剂的设计。另一种值得考虑的方法是串联多种成熟的催化反应(如甲醇合成、二氧化碳-费歇尔-特罗普合成、RWGS、合成气转化、烯烃水合等),间接实现二氧化碳转化为高级醇,而不是直接进行二氧化碳加氢。因此,本综述讨论了这些合成高级醇的替代策略,并评估了它们的潜力。首先,介绍了热力学分析、选择性调整策略以及目前二氧化碳直接加氢所面临的挑战。然后,讨论了多种催化剂的物理集成作为赋予催化剂多功能特性的可行策略。随后,总结了将 CO2 转化为高级醇的几种可行途径以及每种途径所采用的先进催化剂。最后,介绍了不同方法的优点和局限性,强调了串联反应策略在通过二氧化碳转化高效合成高级醇方面所具有的巨大潜力。
Tandem catalysis for CO2 conversion to higher alcohols: A review
In recent years, due to the substantial emission of CO2, global warming has become more severe, and there is an urgent need to develop technologies to reduce greenhouse gas CO2 emissions. Converting CO2 into higher alcohols is a promising process, as it not only produces valuable chemicals but also utilizes CO2 as feedstock. Currently, most reported catalytic approaches are based on direct hydrogenation of CO2 to synthesize higher alcohols. However, the synthesis of higher alcohols involves multiple steps, requiring catalysts with multiple functional sites and their synergistic interactions are crucial. Nevertheless, controlling catalysts at the nanoscale poses challenges, hindering the design of efficient multi-site catalysts. An alternative approach worth considering is to perform a tandem of multiple well-established catalytic reactions (e.g., methanol synthesis, CO2-Fischer-Tropsch-Synthesis, RWGS, syngas conversion, olefin hydration, etc.) to indirectly achieve the conversion of CO2 into higher alcohols, instead of direct CO2 hydrogenation. Therefore, in this review, these alternative strategies of higher alcohols synthesis are discussed, and their potential is evaluated. First, thermodynamic analysis, the selective adjustment strategies, and the current challenges faced for direct CO2 hydrogenation are introduced. Then, physical integration of multiple catalysts as a feasible strategy to endow the catalyst with multifunctional properties is discussed. Subsequently, several feasible routes of CO2 conversion into higher alcohols and the advanced catalysts employed for each pathway are summarized. Finally, merits and limitations of the different approaches are provided, emphasizing the great potential the tandem reaction strategy holds for the efficient synthesis of higher alcohols by CO2 conversion.
期刊介绍:
Applied Catalysis B: Environment and Energy (formerly Applied Catalysis B: Environmental) is a journal that focuses on the transition towards cleaner and more sustainable energy sources. The journal's publications cover a wide range of topics, including:
1.Catalytic elimination of environmental pollutants such as nitrogen oxides, carbon monoxide, sulfur compounds, chlorinated and other organic compounds, and soot emitted from stationary or mobile sources.
2.Basic understanding of catalysts used in environmental pollution abatement, particularly in industrial processes.
3.All aspects of preparation, characterization, activation, deactivation, and regeneration of novel and commercially applicable environmental catalysts.
4.New catalytic routes and processes for the production of clean energy, such as hydrogen generation via catalytic fuel processing, and new catalysts and electrocatalysts for fuel cells.
5.Catalytic reactions that convert wastes into useful products.
6.Clean manufacturing techniques that replace toxic chemicals with environmentally friendly catalysts.
7.Scientific aspects of photocatalytic processes and a basic understanding of photocatalysts as applied to environmental problems.
8.New catalytic combustion technologies and catalysts.
9.New catalytic non-enzymatic transformations of biomass components.
The journal is abstracted and indexed in API Abstracts, Research Alert, Chemical Abstracts, Web of Science, Theoretical Chemical Engineering Abstracts, Engineering, Technology & Applied Sciences, and others.