IN-SITU; REDUCTION; CONVERSION; OXIDATION; ELECTRODE; FORMATE

ACS Appl. Energ. Mater.

2021, 4,

IN-SITU; REDUCTION; CONVERSION; OXIDATION; ELECTRODE; FORMATE

CO2 electroreduction has attracted considerable investigations due to the desirable coupling of renewable energy utilization and value-added chemical production. However, it encounters the bottlenecks of high energy barrier and low efficiency owing to the limited CO2 solubility and mass transfer. Herein, a porous Ni hollow fiber encapsulated Bi@Zeolite catalyst was developed as a self-standing gas diffusion electrode for efficient CO2 reduction to CO. Such a delicate electrode configuration reinforces CO2 adsorption/activation on Bi@Zeolite active sites and favors mass transfer due to a shortened and directed diffusion path. These synergetic promotions induced by Bi@Zeolite encapsulated in Ni hollow fiber achieved a high CO Faradaic efficiency of 74.1% at only an overpotential of 260 mV in the ionic-liquid based electrolyte, which was 2.6 times that on the Ni foil planar configuration. In addition, both CO Faradaic efficiency and current density remained almost constant for the duration of a 16 h test, further indicating the superiority of the Ni hollow fiber encapsulated configuration. This work demonstrates the potential of using a hollow fiber to reinforce reaction kinetics for efficient CO2 electroreduction.