精炼(冶金)
电合成
可再生能源
材料科学
碳纤维
电解
生化工程
纳米技术
燃料电池
电催化剂
支化(高分子化学)
电解水
单体
能量载体
生产(经济)
二聚体
化学
工艺工程
催化作用
碳捕获和储存(时间表)
还原(数学)
作者
Ruiqi Guo,Caihong Fan,Yansong Zhou,Qianqian Yan,Tianyu Qiu,Ruisong Li,Jing Li,Shuyu Zhang,Peilin Deng,Xinlong Tian,Zhitong Wang
摘要
ABSTRACT Electrocatalytic CO 2 reduction reaction utilizes renewable energy to convert CO 2 into fuels and chemicals with low carbon footprint, standing as a promising technology for addressing climate change, energy decarbonization, and industrial revolution. However, the multielectron reduction steps typically involve complicated reaction pathways and competing key intermediates, resulting in the electrosynthesis of highly valuable multicarbon products inferior to the single carbon counterparts. In this contribution, state‐of‐the‐art progress regarding multicarbon production from a micro‐mechanism viewpoint is comprehensively overviewed, starting from fundamental reaction pathways to underline C─C coupling and route branching in regulating product distribution. Subsequently, the promotional approaches for the dimerization of carbonaceous monomers are thoroughly discussed from the thermodynamic and kinetic perspectives, and strategies for regulating the bond evolution of dimer intermediates are elucidated. Finally, challenges and innovative opportunities in theoretical exploration, dynamic service, and industrial scaling‐up are identified, delineating a viable roadmap for refining the artificial carbon cycle.
科研通智能强力驱动
Strongly Powered by AbleSci AI