Dual-Role of Polyelectrolyte-Tethered Benzimidazolium Cation in Promoting CO2 /Pure Water Co-Electrolysis to Ethylene

Abstract

Electrochemical CO₂ reduction reaction (CO₂ RR), as a promising route to realize negative carbon emissions, is known to be strongly affected by electrolyte cations (i.e., cation effect). In contrast to the widely-studied alkali cations in liquid electrolytes, the effect of organic cations grafted on alkaline polyelectrolytes (APE) remains unexplored, although APE has already become an essential component of CO₂ electrolyzers. Herein, by studying the organic cation effect on CO₂ RR, we find that benzimidazolium cation (Beim⁺ ) significantly outperforms other commonly-used nitrogenous cations (R₄ N⁺ ) in promoting C₂₊ (mainly C₂ H₄ ) production over copper electrode. Cyclic voltammetry and in situ spectroscopy studies reveal that the Beim⁺ can synergistically boost the CO₂ to *CO conversion and reduce the proton supply at the electrocatalytic interface, thus facilitating the *CO dimerization toward C₂₊ formation. By utilizing the homemade APE ionomer, we further realize efficient C₂ H₄ production at an industrial-scale current density of 331 mA cm^-2 from CO₂ /pure water co-electrolysis, thanks to the dual-role of Beim⁺ in synergistic catalysis and ionic conduction. This study provides a new avenue to boost CO₂ RR through the structural design of polyelectrolytes.

Keywords: Benzimidazolium Cation; Cation Effect; Electrochemical CO2 Reduction; Ethylene; Polyelectrolyte.