甲酸
甲醇
二氧化碳电化学还原
原材料
催化作用
法拉第效率
氢燃料
化学
电化学
碳纤维
氢经济
可持续能源
燃料电池
氢
电催化剂
可再生能源
二氧化碳
纳米技术
可再生燃料
能量载体
废物管理
液体燃料
无机化学
制氢
蒸汽重整
能量转换
材料科学
化学工程
高效能源利用
合成燃料
合成气
有机化学
环境科学
作者
Pavlina Karapapa,Shobhan Mondal,Erica Zeglio,Biswanath Das
标识
DOI:10.1002/anie.202522226
摘要
Abstract Transforming carbon dioxide (CO 2 ) into formic acid (HCOOH) and methanol (CH 3 OH) as C 1 liquid fuels is central to advancing circular carbon economies and sustainable energy applications. Both CH 3 OH and HCOOH possess high energy density and are easily storable and transportable. Beyond their widespread use as solvents and C 1 feedstock chemicals, CH 3 OH can be applied in fuel cells or serve as a hydrogen precursor, making it valuable for transportation and grid‐level energy storage. HCOOH similarly functions as a safe hydrogen carrier and as a fuel in formic acid fuel cells. Electrochemical CO 2 reduction (eCO 2 R) to these C 1 products represents a pivotal step in closing the anthropogenic carbon loop, enabling sustainable energy storage. Recent years have brought notable advances in catalyst development, mechanistic understanding, and system optimization. Although metal‐free catalysts and conductive polymers have advanced at a fast pace, transition‐metal‐containing systems remain the most effective, offering superior activity, selectivity, stability, and Faradaic efficiency (FE). Particularly promising are dual‐function systems that integrate CO 2 capture/absorption with electroreduction, offering a promising route toward the direct valorization of industrial CO 2 emissions. This minireview critically evaluates recent advances in molecular and polymer‐based electrocatalytic systems, design strategies, and emerging directions for next‐generation CO 2 ‐to‐C 1 liquid fuel conversion technologies.
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