Achieving precise control over reaction pathways in the electrochemical CO2 reduction reaction (CO2RR) is a central challenge. Silver, for instance, is widely recognized for its high selectivity toward carbon monoxide (CO). Here, we demonstrate a strategy to steer the selectivity of Ag away from CO and toward formic acid (HCOOH) by engineering the nanoscale structure of water at the electrode-electrolyte interface. Using a polymeric cation, poly(diallyldimethylammonium chloride) (PDDA), in an alkali-metal-cation-free, strongly acidic electrolyte, we create a hydrophobic interfacial environment that promotes weakly hydrogen-bonded, "free-like" water (f-H2O). Using operando spectroscopy and isotope labeling, we establish a direct, quantitative correlation between the abundance of f-H2O and HCOOH selectivity. Electrochemical analyses and theoretical simulations using density functional theory and ab initio molecular dynamics suggest that the f-H2O-rich environment opens a distinct mechanistic channel for HCOOH formation via a direct, energetically favorable *H + CO2 hydrogenation reaction, a pathway disfavored in conventional alkali-metal-cation-based electrolytes where strongly hydrogen-bonded water (h-H2O) facilitates the *COOH pathway to CO. These findings highlight that the tuning of interfacial water structure is powerful in overriding the intrinsic selectivity of a catalyst and rationally directing CO2RR pathways.
Yang et al. (Tue,) studied this question.
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