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Switching between C₂₊ Products and CH₄ in CO₂ Electrolysis by Tuning the Composition and Structure of Rare-Earth/Copper Catalysts

Journal of the American Chemical Society2023Vol. 145(42), pp. 23037–23047

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Jiyuan Liu, Pengsong Li, Jiahui Bi, Shuaiqiang Jia, Yong Wang, Xinchen Kang, Xiaofu Sun, Qinggong Zhu, Buxing Han

Abstract

Rational regulation of the reaction pathway to produce the desired products is one of the most significant challenges in the electrochemical CO₂ reduction reaction (CO₂RR). Herein, we designed a series of rare-earth Cu catalysts with mixed phases. It was found that the products could be switched from C₂₊ to CH₄ by tuning the composition and structure of the catalysts. Particularly at the Cu/Sm atomic ratio of 9/1 (Cu₉Sm₁-O_x), the Faradaic efficiency (FE) for C₂₊ products (FE_C₂₊) could reach 81% at 700 mA cm-2 with negligible CH₄. However, the FE of CH₄ (FE_CH₄) was 65% at 500 mA cm-2 over Cu₁Sm₉-O_x (Cu/Sm = 1/9), and the FE_C₂₊ was extremely low. Experiments and theoretical studies indicated that the stable CuSm₂O₄ phase existed in all the catalysts within the Cu/Sm range of 9/1 to 1/9. At a high Cu content, the catalyst was composed of CuSm₂O₄ and Cu phases. The small amount of Sm could enhance the binding strength of *CO and facilitate C-C coupling. Conversely, at a high Sm content, the catalyst was composed of CuSm₂O₄ and Sm₂O₃ phases. Sm could effectively stabilize bivalent Cu and enrich proton donors, lowering the reaction energy of *CO for deep hydrogenation to generate CH₄. In both pathways, the stable CuSm₂O₄ phase could cooperate with the Cu or Sm₂O₃ phases, which induced the formation of different microenvironments to generate different products. This strategy also had commonality with other Cu-rare-earth (La, Pr, and Eu) catalysts to boost the CO₂RR for C₂₊ or CH₄ production.

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Abstract

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