Steric and hydrophilic/hydrophobic effects of organic cations on electrochemical CO reduction
Liwei XUE, Fengyuan Wei, Jieyu Wang, Xuelin Huang, Huijuan Wang, Guangzhe Wang, Li Xiao, Gongwei Wang, Lin Zhuang, Gongwei Wang, Lin Zhuang
Abstract
The identity of cations plays a critical role in electrochemical CO2 and CO reduction reactions. While most research has focused on elucidating the effects of alkali metal cations, the influence of organic cations, which are widely employed in practical anion exchange membrane (AEM) electrolyzers, remains underexplored. Here, we systematically investigate the effects of a series of organic cations with varying sizes and hydrophilic/hydrophobic properties on the CO reduction reaction (CORR). By combining electrochemical online mass spectrometry for kinetic analysis, in-situ Raman spectroscopy for interfacial species characterization, and ab initio molecular dynamics (AIMD) simulations to probe interfacial structures, we uncover that the structure of organic cations significantly influences the accessibility of interfacial water to the electrode surface, and thus the potential-dependent behavior of surface *H coverage, ultimately modulating the CORR selectivity. These findings provide new insights into the mechanisms governing CORR and can guide the development of efficient AEM electrolyzers for CO conversion. Understanding the organic cation effect on CO electroreduction is crucial for developing efficient alkaline polyelectrolytes. Here, the authors elucidate how organic cations of varying sizes and hydrophilicity influence the electrocatalytic interface and product selectivity during CO reduction.