Efficient Capture and Electroreduction of Dilute CO 2 into Highly Pure and Concentrated Formic Acid Aqueous Solution.
Zhen-Hua ZhaoJia-Run HuangDa-Shuai HuangHao-Lin ZhuPei-Qin LiaoXiao-Ming ChenPublished in: Journal of the American Chemical Society (2024)
High-purity CO 2 rather than dilute CO 2 (15 vol %, CO 2 /N 2 /O 2 = 15:80:5, v/v/v) similar to the flue gas is currently used as the feedstock for the electroreduction of CO 2 , and the liquid products are usually mixed up with the cathode electrolyte, resulting in high product separation costs. In this work, we showed that a microporous conductive Bi-based metal-organic framework ( Bi-HHTP , HHTP = 2,3,6,7,10,11-hexahydroxytriphenylene) can not only efficiently capture CO 2 from the dilute CO 2 under high humidity but also catalyze the electroreduction of the adsorbed CO 2 into formic acid with a high current density of 80 mA cm -2 and a Faradaic efficiency of 90% at a very low cell voltage of 2.6 V. Importantly, the performance in a dilute CO 2 atmosphere was close to that under a high-purity CO 2 atmosphere. This is the first catalyst that can maintain exceptional eCO 2 RR performance in the presence of both O 2 and N 2 . Moreover, by using dilute CO 2 as the feedstock, a 1 cm -2 working electrode coating with Bi-HHTP can continuously produce a 200 mM formic acid aqueous solution with a relative purity of 100% for at least 30 h in a membrane electrode assembly (MEA) electrolyzer. The product does not contain electrolytes, and such a highly concentrated and pure formic acid aqueous solution can be directly used as an electrolyte for formic acid fuel cells. Comprehensive studies revealed that such a high performance might be ascribed to the CO 2 capture ability of the micropores on Bi-HHTP and the lower Gibbs free energy of formation of the key intermediate *OCHO on the open Bi sites.