Selective electrocatalytic reduction of CO2 to formate via carbon-shell-encapsulated In2O3 nanoparticles/graphene nanohybrids

Constructing nanohybrids with a synergistic effect using multi-components and specific micro/nanostructures can significantly enhance their electrocatalytic activity. In this work, we fabricated an InO?NC@GO nanohybrid, in which InOnanoparticles (NPs) were encapsulated by an N-doped carbon(NC) shell and supported on graphene. The multi-components in InO?NC@GO synergistically optimize the structural and electronic properties of the material. The particle size and dispersion of InONPs were optimized owing to the separation effect of the amorphous NC shell and graphene support. This separation effect exposes more number of active sites for the electrochemical reaction. Abundant oxygen vacancies exist in InO, leading to a stronger ability for the adsorption and activation of CO. The NC shell inhibits the direct contact between the electrolyte and InO, which significantly suppresses competitive Hevolution. The charge transfer during the electrocatalysis process is also effectively enhanced due to the carbon components. The synergistic effect of multi-components in the InO?NC@GO sample results in a significantly improved COreduction reaction performance with a high HCOO~–Faradic efficiency (FE) of 91.2% and a current density of 40.38 m A cmat –0.8 V obtained using a flow cell.The present work demonstrates that rationally designing nanohybrids with multifunctional components is an effective strategy for optimizing the structural and electrocatalytic properties of materials for energy conversion.