Carbon dioxide electroreduction (CO2R) in acid tends to be a promising route to avoid CO2 loss in alkaline and neutral electrolytes; however, high alkali cation concentrations (typically ≥3 M) are required to activate CO2 and suppress water electroreduction, causing carbonate formation and thus unsatisfied single-pass carbon efficiency (SPCE). Based on theoretical and experimental analyses, we show that an inherent trade-off exists: increasing cation concentrations improves Faradaic efficiency (FE) toward CO2R products but comes at the expense of reduced SPCE. We demonstrate a polyimide-modification strategy to overcome this trade-off by taking advantage of the amino groups that can effectively capture protons, creating a local alkaline microenvironment surrounding the electrode surface. In a proof-of-concept experiment, SnO2 nanoparticles were modified with polyimide and acted as a CO2R catalyst, which achieved, simultaneously, near-ideal SPCE of 95.7% and FE of 96% (toward HCOOH) at pH 1.36 with dilute potassium ions down to even 0.1 M. We expect that these findings will accelerate the development of carbon- and electron-efficient acidic CO2 electrolysis.
Keywords: Acidic CO2 electrolysis; Carbon efficiency; Formic acid; Polyimide‐modification; Trade‐off.
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