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Asymmetrical electrohydrogenation of CO 2 to ethanol with copper-gold heterojunctions.

Siyu KuangYa-Qiong SuMinglu LiHai LiuHongyuan ChuaiXiaoyi ChenEmiel J M HensenThomas J MeyerSheng ZhangXinbin Ma
Published in: Proceedings of the National Academy of Sciences of the United States of America (2023)
Copper is distinctive in electrocatalyzing reduction of CO 2 into various energy-dense forms, but it often suffers from limited product selectivity including ethanol in competition with ethylene. Here, we describe systematically designed, bimetallic electrocatalysts based on copper/gold heterojunctions with a faradaic efficiency toward ethanol of 60% at currents in excess of 500 mA cm -2 . In the modified catalyst, the ratio of ethanol to ethylene is enhanced by a factor of 200 compared to copper catalysts. Analysis by ATR-IR measurements under operating conditions, and by computational simulations, suggests that reduction of CO 2 at the copper/gold heterojunction is dominated by generation of the intermediate OCCOH*. The latter is a key contributor in the overall, asymmetrical electrohydrogenation of CO 2 giving ethanol rather than ethylene.
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