Molecular tuning of CO2-to-ethylene conversion

法拉第效率 乙烯 电解质 二氧化碳电化学还原 电化学 氧化还原 化学 化学工程 催化作用 吸附 纳米技术 可再生能源 材料科学 无机化学 光化学 分子 电极 有机化学 一氧化碳 物理化学 工程类 电气工程
作者
Fengwang Li,Arnaud Thevenon,Alonso Rosas‐Hernández,Ziyun Wang,Yilin Li,Christine M. Gabardo,Adnan Ozden,Cao‐Thang Dinh,Jun Li,Yuhang Wang,Jonathan P. Edwards,Yi Xu,Christopher McCallum,Lizhi Tao,Zhiqin Liang,Mingchuan Luo,Xue Wang,Huihui Li,Colin P. O’Brien,Chih‐Shan Tan
出处
期刊:Nature [Nature Portfolio]
卷期号:577 (7791): 509-513 被引量:1232
标识
DOI:10.1038/s41586-019-1782-2
摘要

The electrocatalytic reduction of carbon dioxide, powered by renewable electricity, to produce valuable fuels and feedstocks provides a sustainable and carbon-neutral approach to the storage of energy produced by intermittent renewable sources1. However, the highly selective generation of economically desirable products such as ethylene from the carbon dioxide reduction reaction (CO2RR) remains a challenge2. Tuning the stabilities of intermediates to favour a desired reaction pathway can improve selectivity3–5, and this has recently been explored for the reaction on copper by controlling morphology6, grain boundaries7, facets8, oxidation state9 and dopants10. Unfortunately, the Faradaic efficiency for ethylene is still low in neutral media (60 per cent at a partial current density of 7 milliamperes per square centimetre in the best catalyst reported so far9), resulting in a low energy efficiency. Here we present a molecular tuning strategy—the functionalization of the surface of electrocatalysts with organic molecules—that stabilizes intermediates for more selective CO2RR to ethylene. Using electrochemical, operando/in situ spectroscopic and computational studies, we investigate the influence of a library of molecules, derived by electro-dimerization of arylpyridiniums11, adsorbed on copper. We find that the adhered molecules improve the stabilization of an ‘atop-bound’ CO intermediate (that is, an intermediate bound to a single copper atom), thereby favouring further reduction to ethylene. As a result of this strategy, we report the CO2RR to ethylene with a Faradaic efficiency of 72 per cent at a partial current density of 230 milliamperes per square centimetre in a liquid-electrolyte flow cell in a neutral medium. We report stable ethylene electrosynthesis for 190 hours in a system based on a membrane-electrode assembly that provides a full-cell energy efficiency of 20 per cent. We anticipate that this may be generalized to enable molecular strategies to complement heterogeneous catalysts by stabilizing intermediates through local molecular tuning. Electrocatalytic reduction of CO2 over copper can be made highly selective by ‘tuning’ the copper surface with adsorbed organic molecules to stabilize intermediates for carbon-based fuels such as ethylene
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