Engineering Atomically Dispersed FeN4 Active Sites for CO2 Electroreduction

Atomically dispersed FeN4 active sites have exhibited exceptional catalytic activity and selectivity for the electrochemical CO2 reduction reaction (CO2RR) to CO. However, the understanding behind the intrinsic and morphological factors contributing to the catalytic properties of FeN4 sites is still lacking. By using a Fe-N-C model catalyst derived from the ZIF-8, we deconvoluted three key morphological and structural elements of FeN4 sites, including particle sizes of catalysts, Fe content, and Fe-N bond structures. Their respective impacts on the CO2RR were comprehensively elucidated. Engineering the particle size and Fe doping is critical to control extrinsic morphological factors of FeN4 sites for optimal porosity, electrochemically active surface areas, and the graphitization of the carbon support. In contrast, the intrinsic activity of FeN4 sites was only tunable by varying thermal activation temperatures during the formation of FeN4 sites, which impacted the length of the Fe-N bonds and the local strains. The structural evolution of Fe-N bonds was examined at the atomic level. First-principles calculations further elucidated the origin of intrinsic activity improvement associated with the optimal local strain of the Fe-N bond.

Automated summary

Atomically dispersed FeN4 active sites show exceptional catalytic activity for electrochemical CO2 reduction to CO. Controlling particle size and Fe doping is crucial for optimizing the extrinsic catalytic properties of FeN4 sites, while intrinsic activity can be tuned by varying thermal activation temperatures during FeN4 site formation. Structural evolution of Fe-N bonds plays a key role in understanding the origin of intrinsic activity improvement.