Abstract
Electrochemical CO(2) reduction reaction (CO(2)RR) to multicarbon (C(2+)) products faces challenges of unsatisfactory selectivity and stability. Guided by finite element method (FEM) simulation, a nanoreactor with cavity structure can facilitate C-C coupling by enriching *CO intermediates, thus enhancing the selectivity of C(2+) products. We designed a stable carbon-based nanoreactor with cavity structure and Cu active sites. The unique geometric structure endows the carbon-based nanoreactor with a remarkable C(2+) product faradaic efficiency (80.5%) and C(2+)-to-C(1) selectivity (8.1) during the CO(2) electroreduction. Furthermore, it shows that the carbon shell could efficiently stabilize and highly disperse the Cu active sites for above 20 hours of testing. A remarkable C(2+) partial current density of-323 mA cm(-2) was also achieved in a flow cell device. In situ Raman spectra and density functional theory (DFT) calculation studies validated that the *CO(atop) intermediates are concentrated in the nanoreactor, which reduces the free energy of C-C coupling. This work unveiled a simple catalyst design strategy that would be applied to improve C(2+) product selectivity and stability by rationalizing the geometric structures and components of catalysts.