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Atomic Eu Substitution in Cu <sub>2</sub> O Tailors C <sub>1</sub> and C <sub>2+</sub> Product Selectivity by Frustrated Deep Hydrogenation in Electrochemical CO <sub>2</sub> Reduction

Yang Liu, Xuan Wang, Zichun Mao, J. Q. Zhang, Meng Li, Dongmei Sun, Yawen Tang, Hao Li, Gengtao Fu

2025Journal of the American Chemical Society17 citationsDOI

Abstract

The electrochemical CO 2 reduction reaction (eCO 2 RR) is an important method to obtain high-value chemicals; however, selectively tailoring C 1 and C 2+ products remains a challenge. Herein, we propose a novel and effective rare-earth Eu substitution strategy to tailor the selectivity of C 1 and C 2+ products on Cu 2 O sites by frustrated deep hydrogenation in the eCO 2 RR. The incorporation of atomic Eu into Cu 2 O can shift the dominant product from C 2+ at low Eu content to CH 4 at high Eu content. For low Eu-doped Cu 2 O (LD-Eu/Cu 2 O), the total Faradaic efficiency (FE) of C 2+ products reaches 79.39% with ethylene (C 2 H 4 ) as the predominant product (FE: 49.27%) in the H-type cell; whereas high Eu-doped Cu 2 O (HD-Eu/Cu 2 O) promotes the formation of C 1 products, achieving a total FE of 50.25% with methane (CH 4 ) as the main product (FE: 47.21%). Eu substitution for tailoring the selectivity of C 1 and C 2+ products on the Cu 2 O site is also verified in the flow cell. Electrochemical in situ characterization and theoretical calculations suggest that low levels of Eu incorporation in Cu 2 O weakens the π* antibonding interaction over the C═O bond, facilitating C–C coupling to lead the C 2+ pathway via the frustrated deep hydrogenation of *CHO; whereas high Eu incorporation in Cu 2 O strengthens the π* antibonding interaction, facilitating the deep hydrogenation of *CHO to CH 4 via the C 1 pathway. This work provides a new perspective on tailoring product selectivity by rare-earth-induced frustrated deep hydrogenation during the eCO 2 RR.

Topics & Concepts

ChemistryAntibonding molecular orbitalSelectivityElectrochemistrySubstitution (logic)Faraday efficiencyYield (engineering)PhotochemistryProduct (mathematics)Inorganic chemistryEthyleneMethaneCombinatorial chemistryGreen chemistryCO2 Reduction Techniques and CatalystsAmmonia Synthesis and Nitrogen ReductionCarbon dioxide utilization in catalysis