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Abstract The electrocatalytic carbon dioxide or carbon monoxide reduction reaction (CO 2 RR or CORR) features a sustainable method for reducing carbon emissions and producing value‐added chemicals. However, the generation of C 3 products with higher energy density and market values, such as n‐propanol, remains highly challenging, which is attributed to the unclear formation mechanism of C 3+ versus C 2 products. In this work, by the Tafel slope analysis, electrolyte pH correlation exploration, and the kinetic analysis of CO partial pressure fitting, it is identified that both n‐propanol and C 2 products share the same rate‐determining step, which is the coupling of two C 1 intermediates via the derivation of the Butler–Volmer equation. In addition, inspired by the mechanistic study, it is proposed that a high OH ─ concentration and a water‐limited environment are beneficial for promoting the subsequent *C 2 –*C 1 coupling to n‐propanol. At 5.0 m OH − , the partial current density of producing n‐propanol ( j n‐propanol ) reached 45 mA cm −2 , which is 35 and 1.3 times higher than that at 0.01 m OH − and 1.0 m OH − , respectively. This study provides a comprehensive kinetic analysis of n‐propanol production and suggests opportunities for designing new catalytic systems for promoting the C 3 production.
Yan et al. (Wed,) studied this question.