Efficient electrocatalytic CO2 reduction on a three-phase interface

Abstract

Electrochemical CO2 reduction is a critical approach to reducing the globally accelerating CO2 emission and generating value-added products. Despite great efforts to optimize catalyst activity and selectivity, facilitating the catalyst accessibility to high CO2 concentrations while maintaining electrode durability remains a significant challenge. Here, we designed a catalytic system that mimics the alveolus structure in mammalian lungs with high gas permeability but very low water diffusibility, enabling an array of three-phase catalytic interfaces. Flexible, hydrophobic, nanoporous polyethylene membranes with high gas permeability were used to enable efficient CO2 access and a high local alkalinity on the catalyst surface at different CO2 flow rates. Such an alveolus-mimicking structure generates a high CO production Faradaic efficiency of 92% and excellent geometric current densities of CO production (25.5 mA cm−2) at −0.6 V versus the reversible hydrogen electrode, with a very thin catalyst thickness of 20−80 nm. The efficient design of electrochemical CO2 reduction catalysts requires high CO2 concentrations on the catalyst surface. Here, Cui and co-workers make use of flexible, hydrophobic, nanoporous polyethylene membranes with good gas permeability to design a catalytic set-up that mimics the alveolus structure in mammalian lungs, achieving high activity and selectivity to CO.