Unintended cation crossover influences CO2 reduction selectivity in Cu-based zero-gap electrolysers

Membrane electrode assemblies enable CO 2 electrolysis at industrially relevant rates, yet their operational stability is often limited by formation of solid precipitates in the cathode pores, triggered by cation crossover from the anolyte due to imperfect ion exclusion by anion exchange membranes. Here we show that anolyte concentration affects the degree of cation movement through the membranes, and this substantially influences the behaviors of copper catalysts in catholyte-free CO 2 electrolysers. Systematic variation of the anolyte (KOH or KHCO 3 ) ionic strength produced a distinct switch in selectivity between either predominantly CO or C 2+ products (mainly C 2 H 4 ) which closely correlated with the quantity of alkali metal cation (K + ) crossover, suggesting cations play a key role in C-C coupling reaction pathways even in cells without discrete liquid catholytes. Operando X-ray absorption and quasi in situ X-ray photoelectron spectroscopy revealed that the Cu surface speciation showed a strong dependence on the anolyte concentration, wherein dilute anolytes resulted in a mixture of Cu + and Cu 0 surface species, while concentrated anolytes led to exclusively Cu 0 under similar testing conditions. These results show that even in catholyte-free cells, cation effects (including unintentional ones) significantly influence reaction pathways, important to consider in future development of catalysts and devices. Cation cross-over affects CO 2 electroreduction process, yet the detailed effect, especially the cation effect in promising membrane electrode assemblies, needs further investigation. Here the authors reveal that unintentional cation crossover through anion exchange membranes during CO 2 electrolysis influences product selectivity towards carbon monoxide or ethylene.