电解质
电极
法拉第电流
化学工程
气体扩散
电化学
碳化作用
电解
阴极
化学
气体扩散电极
法拉第效率
无机化学
碱度
材料科学
电极电位
有机化学
物理化学
工程类
作者
McLain Leonard,Lauren E. Clarke,Antoni Forner‐Cuenca,Steven M. Brown,Fikile R. Brushett
出处
期刊:Chemsuschem
[Wiley]
日期:2019-11-17
卷期号:13 (2): 400-411
被引量:329
标识
DOI:10.1002/cssc.201902547
摘要
Abstract Managing the gas–liquid interface within gas‐diffusion electrodes (GDEs) is key to maintaining high product selectivities in carbon dioxide electroreduction. By screening silver‐catalyzed GDEs over a range of applied current densities, an inverse correlation was observed between carbon monoxide selectivity and the electrochemical double‐layer capacitance, a proxy for wetted electrode area. Plotting current‐dependent performance as a function of cumulative charge led to data collapse onto a single sigmoidal curve indicating that the passage of faradaic current accelerates flooding. It was hypothesized that high cathode alkalinity, driven by both initial electrolyte conditions and cathode half‐reactions, promotes carbonate formation and precipitation which, in turn, facilitates electrolyte permeation. This mechanism was reinforced by the observations that post‐test GDEs retain less hydrophobicity than pristine materials and that water‐rinsing and drying electrodes temporarily recovers peak selectivity. This knowledge offers an opportunity to design electrodes with greater carbonation tolerance to improve device longevity.
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