化学
电合成
电解质
电解
质子输运
催化作用
法拉第效率
质子交换膜燃料电池
化学工程
无机化学
电极
电解水
离解(化学)
膜电极组件
哌嗪
阴极
本体电解
膜
电解槽
质子
支撑电解质
原电池
溶剂
作者
Sixing Zheng,Junyi Han,Zhenhui Kou,Nengji Liu,Yaqi Chen,Bin Yang,Zhongjian Li,Fei Song,Lecheng Lei,Evgeniya Sheremet,Tao Zhang,Jong-Beom Baek,Yang Hou
摘要
Ampere-level ethanol electrosynthesis via CO2 electroreduction (CO2ER) critically depends on the dynamic reconstruction of interfacial water networks within the electric double layer (EDL), which provides a confined space for a sustained proton supply. Conventional reconstruction strategies like electrolyte engineering, however, introduce spatial heterogeneity. This causes local variations in activity and selectivity, especially in membrane electrode assembly (MEA) electrolyzers, where scarce cathodic electrolyte worsens proton transport limitations. Here, we introduce a bidentate-N-enriched organic interlayer that strategically modulates the orientation of interfacial water molecules, thereby enhancing proton supply and optimizing hydrogenation kinetics. In situ spectroscopy and theoretical simulations reveal that the piperazine layer promotes water dissociation through interfacial reorientation, thus accelerating *CO → *CHO hydrogenation and asymmetric *CHO-*CO coupling for selective ethanol production. The piperazine-modified Cu catalyst achieves >85% C2+ Faradaic efficiencies (FEs) at 400-1000 mA cm-2 and 50.5% ethanol FEs in a flow cell and maintains 40.1% ethanol FEs at 2.0 A in the MEA electrolyzer. This work provides a molecular-level design strategy to tailor electrolytic interfaces for CO2 conversion at the electrolyzer level.
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