Abstract
The efficient electrochemical CO(2) reduction to C(2+) products at high current densities remains a significant challenge. Here we show inherently hydrophobic and hierarchically porous Cu supraparticles comprising sub-10 nm Cu constituent particles for ampere-level CO(2)-to-C(2+) electrosynthesis. These supraparticles feature abundant grain boundaries for high C(2+) selectivity, coupled with interconnected mesopores and interparticle macropore cavities to enhance the accessibility of the active sites and mass transfer, breaking the trade-off between activity and mass transfer in Cu-based catalysts. Moreover, the intrinsic hydrophobicity of the supraparticles mitigates the water-flooding issue of catalytic layer in flow cells, improving the stability at high current densities. Consequently, the Cu supraparticles achieve ampere-level CO(2) electrolysis up to 3.2 A cm(-2) with a C(2+) Faradaic efficiency of 74.9% (compared to 1.21 A cm(-2) and 55.4% for Cu nanoparticles) and maintain stability at 1 A cm(-2) for over 100 h. This work provides profound insights into the effect of the coupling of mass transfer and catalytic reaction under a high current and presents a corresponding solution by superstructure design.