Mark Sassenburg, H P Iglesias van Montfort, Nikita Kolobov, Wilson A Smith, Thomas Burdyny
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引用次数: 0
摘要
二氧化碳(CO2)的电化学还原为封闭碳循环和获得可持续来源的碳化合物提供了机会。近年来,铜作为唯一能够有效产生多碳(C2+)物种的催化剂受到广泛关注。值得注意的是,一氧化碳(CO)也可以在铜上还原成 C2+ 化合物,这就促使人们将铜与银等产生 CO 的物质串联起来,以提高 C2+ 的整体选择性。在这项工作中,我们通过改变产生 CO 的银层的位置和比例,研究了铜和银的分层组合的影响。我们的报告显示,C2+ 含氧酸选择性从 100 纳米铜层的 23% 有效提高到 100:15 纳米铜:银层的 38%。但值得注意的是,在所有共催化剂情况下,即使是 5 nm 的银层,CO 的产生量也比单独使用 Cu 时多。最后,由于铜层的重组和层间流动性,铜的稳定性显然限制了这种串联溶液的位置优势。
Bulk Layering Effects of Ag and Cu for Tandem CO2 Electrolysis.
The electrochemical reduction of carbon dioxide (CO2) presents an opportunity to close the carbon cycle and obtain sustainably sourced carbon compounds. In recent years, copper has received widespread attention as the only catalyst capable of meaningfully producing multi-carbon (C2+) species. Notably carbon monoxide (CO) can also be reduced to C2+ compounds on copper, motivating tandem systems that combine copper and CO-producing species, like silver, to enhance overall C2+ selectivities. In this work, we examine the impact of layered-combinations of bulk Cu and Ag by varying the location and proportion of the CO-producing Ag layer. We report an effective increase in the C2+ oxygenate selectivity from 23 % with a 100 nm Cu to 38 % for a 100 : 15 nm Cu : Ag layer. Notably, however, for all co-catalyst cases there is an overproduction of CO vs Cu alone, even for 5 nm Ag layers. Lastly, due to restructuring and interlayer mobility of the copper layer it is clear that the stability of copper limits the locational advantages of such tandem solutions.
期刊介绍:
ChemSusChem
Impact Factor (2016): 7.226
Scope:
Interdisciplinary journal
Focuses on research at the interface of chemistry and sustainability
Features the best research on sustainability and energy
Areas Covered:
Chemistry
Materials Science
Chemical Engineering
Biotechnology
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