电极
材料科学
法拉第效率
电解
化学工程
解吸
可逆氢电极
动能
氢
气体扩散电极
串联
高效能源利用
电解水
电化学
纳米技术
碱性水电解
扩散
热的
热能
动力学
联轴节(管道)
Boosting(机器学习)
高温电解
活化能
化学能
水煤气变换反应
化学动力学
科技与社会
热力学
电流(流体)
能量转换
作者
Lina Hu,Yun Yang,Jiamin Wang,Dongao Zhang,Jingya Huang,Yuqi Zhang,Xiaodong Yi,Guoxiong Wang,Zhou Chen
标识
DOI:10.1038/s41467-026-69506-w
摘要
Electrocatalytic CO2 reduction reaction (CO2RR) technology holds significant industrial potential. However, when faced with elevated-temperature environments caused by industrial-scale operations, the fundamental understanding of temperature-dependent CO2RR behavior in flow cells remains elusive. This study points out that elevated-temperature operation (>333 K) presents both challenges and opportunities for multi-carbon (C2+) production. While elevated temperature enhances reaction kinetics and reduces thermodynamic energy barriers, it simultaneously induces reconstruction of Cu-based catalyst, accelerates gas diffusion electrode flooding, and promotes *CO desorption together with hydrogen evolution reaction, collectively suppressing C2+ product formation and compromising long-term reactor stability. Through rational design of hydrophobic-enhanced Pd-Cu2O/polytetrafluoroethylene (PTFE)/Ag tandem electrodes, we overcome these challenges. Leveraging thermal reduced C-C coupling barriers, the optimized electrode achieves >70% Faradaic efficiency of C2+ across industrially relevant current densities (200–1000 mA cm−2) at 348 K. This strategy converts elevated temperature adversity into a kinetic and thermodynamic advantage, boosting C2+ cathodic energy efficiency by 1.3 times compared to ambient operation, establishing a promising paradigm for industrially viable CO2 electrolysis. The electrocatalytic reduction of CO2 offers industrial potential, but elevated temperatures hinder efficient production of valuable multi-carbon compounds. Here, the authors report a synergistic electrode design for efficient CO2 electrolysis to multicarbon products at 348 K.
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