Enhancing Electroreduction CO<sub>2</sub> to Hydrocarbons via Tandem Electrocatalysis by Incorporation Cu NPs in Boron Imidazolate Frameworks
Ping Shao, Yu‐Mei Wan, Luocai Yi, Shumei Chen, Hai‐Xia Zhang, Jian Zhang
Abstract
Abstract Due to the higher value of deeply‐reduced products, electrocatalytic CO 2 reduction reaction (CO 2 RR) to multi‐electron‐transfer products has received more attention. One attractive strategy is to decouple individual steps within the complicated pathway via multi‐component catalysts design in the concept of tandem catalysts. Here, a composite of Cu@BIF‐144(Zn) (BIF = boron imidazolate framework) is synthesized by using an anion framework BIF‐144(Zn) as host to impregnate Cu 2+ ions that are further reduced to Cu nanoparticles (NPs) via in situ electrochemical transformation. Due to the microenvironment modulation by functional BH(im) 3 − on the pore surfaces, the Cu@BIF‐144(Zn) catalyst exhibits a perfect synergetic effect between the BIF‐144(Zn) host and the Cu NP guest during CO 2 RR. Electrochemistry results show that Cu@BIF‐144(Zn) catalysts can effectively enhance the selectivity and activity for the CO 2 reduction to multi‐electron‐transfer products, with the maximum FE CH4 value of 41.8% at −1.6 V and FE C2H4 value of 12.9% at −1.5 V versus RHE. The Cu@BIF‐144(Zn) tandem catalyst with CO‐rich microenvironment generated by the Zn catalytic center in the BIF‐144(Zn) skeleton enhanced deep reduction on the incorporated Cu NPs for the CO 2 RR to multi‐electron‐transfer products.