Iodide-mediated electroreduction of carbon dioxide for efficient and selective electrosynthesis of multicarbon products over copper iodide microcrystals.

Electrochemical CO reduction (e-CORR) to multicarbon (C) products serves as a sustainable route for renewable energy storage, chemical synthesis, and mitigating CO emission. In this study, we report on the CuI microcrystals modified gas-diffusion electrode (microCuI), prepared with the successive ion layer adsorption and reaction method, with high-performance towards the generation of C products from e-CORR. The microCuI electrode exhibited remarkably high current efficiency towards the generation of C products (i.e., ethylene, ethanol, and 1-propanol), but suffered instability due to the formation of inactive copper (II) carbonate hydroxide within 2-h electrolysis. As compared to other halide ions, the inclusion of a suitable amount of I ions during the electrolysis minimized the corrosion and effectively regulated the oxidation state of surface copper species (OS) and transformed microCuI into aggregates of Cu/CuO nanoparticles, with Cu embedded in a CuO matrix. The suitable OS (∼0.7) combined with synergistic catalytic effects from Cu and CuO enabled high stability and realized high current efficiency (73.6 ± 2.2 %) and high energy efficiency (48.8 ± 1.8 %) for the generation of C products in the prolonged electrolysis at -100 mA cm. Finally, the I ion-mediated e-CORR scheme was also demonstrated to effectively boost the current efficiency and energy efficiency of the microCuI electrode towards the generation of C products from the electrocatalytic reduction of low-concentration CO in the simulated biogas atmosphere.