Haojie Li , Dongxu Song , Xuetao Wang , Xiuquan Li , Gaoyang Lei
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引用次数: 0
Abstract
Hydrogen fuel is considered to be one of the most potential energy sources that can replace fossil fuels in the future. Liquid organic hydrogen carrier formic acid (FA, HCOOH) has been widely concerned in hydrogen production due to its low price, high hydrogen content and the characteristic of easy storage and transportation. The catalyst design and synthesis play an important role in the hydrogen production from FA. The heterogeneous catalysts have become the main focus of research on hydrogen production due to their advantages of more stable, easier separation and higher recycling. In the review, the development of heterogeneous catalysts (reactive metal, catalyst carrier) in catalyzing formic acid decomposition to produce hydrogen are summarized systematacially, the influence of key factors on the overall catalytic hydrogen-producing activity of FA are described in detail. Meanwhile, the review introduces the application of machine learning in catalytic reactions, especially in the strategy of improving the hydrogen production of FA. In the end, the future development trend of hydrogen production from catalytic FA decomposes is prospected. This review can provide a reasonable theoretical basis for designing novel catalysts with high activity and economy in formic acid decomposition to produce hydrogen, and also brings enlightenment for the research direction of formic acid hydrogen production technology.
氢燃料被认为是未来可替代化石燃料的最具潜力的能源之一。液态有机氢载体甲酸(FA,HCOOH)因其价格低廉、氢含量高、易于储存和运输等特点,在制氢领域受到广泛关注。催化剂的设计和合成在甲酸制氢中起着重要作用。异相催化剂因其更稳定、更易分离、更高回收率等优点成为制氢研究的重点。综述系统总结了异相催化剂(活性金属、催化剂载体)在催化甲酸分解制氢方面的发展,详细阐述了关键因素对 FA 整体催化制氢活性的影响。同时,综述介绍了机器学习在催化反应中的应用,尤其是在提高 FA 产氢性能方面的策略。最后,展望了催化 FA 分解制氢的未来发展趋势。本综述可为设计甲酸分解制氢高活性、高经济性的新型催化剂提供合理的理论依据,同时也为甲酸制氢技术的研究方向带来启示。
期刊介绍:
The exploration of energy sources remains a critical matter of study. For the past nine decades, fuel has consistently held the forefront in primary research efforts within the field of energy science. This area of investigation encompasses a wide range of subjects, with a particular emphasis on emerging concerns like environmental factors and pollution.