Noémi V Galbicsek, Attila Kormányos, Gergely Ferenc Samu, Mohd M Ayyub, Tomaž Kotnik, Sebastijan Kovačič, Csaba Janáky, Balázs Endrődi
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引用次数: 0
摘要
一氧化碳的电化学还原为通过两个连续的电化学反应从二氧化碳生产有价值的化学品(如醋酸、乙醇或乙烯)提供了一条可行的途径。这种深度还原产物是通过每个一氧化碳分子转移 4-6 个电子形成的。假设二氧化碳电解槽和一氧化碳电解槽的大小相似,后者需要 2-3 倍大的电流密度才能达到摩尔通量。通过调整气体扩散电极的结构,可以确保如此高的反应速率。在这里,我们使用不同的聚合物粘合剂系统地改变阴极催化剂层的结构,以实现高反应速率。对具有相同骨架但不同官能团的简单线性聚合物进行了比较,以突出不同结构图案的作用。比较范围还扩大到简单的线性部分氟化聚合物。有趣的是,在某些情况下,得到的结果与目前最先进的粘合剂相似。通过使用不同的表面润湿表征技术,我们发现粘合剂提供的催化剂层的疏水性是高倍率 CO 电解的先决条件。我们使用 PVDF 作为催化剂粘合剂,在高电流密度(1 A cm-2)下进行了几个小时的一氧化碳电解实验,证明了这一观点的正确性。
Comparative Study of Different Polymeric Binders in Electrochemical CO Reduction.
Electrochemical reduction of carbon monoxide offers a possible route to produce valuable chemicals (such as acetate, ethanol or ethylene) from CO2 in two consecutive electrochemical reactions. Such deeply reduced products are formed via the transfer of 4-6 electrons per CO molecule. Assuming similar-sized CO2 and CO electrolyzers, 2-3-times larger current densities are required in the latter case to match the molar fluxes. Such high reaction rates can be ensured by tailoring the structure of the gas diffusion electrodes. Here, the structure of the cathode catalyst layer was systematically varied using different polymeric binders to achieve high reaction rates. Simple linear polymers, bearing the same backbone but different functional groups were compared to highlight the role of different structural motifs. The comparison was also extended to simple linear, partially fluorinated polymers. Interestingly, in some cases similar results were obtained as with the current state-of-the-art binders. Using different surface-wetting characterization techniques, we show that the hydrophobicity of the catalyst layer-provided by the binder- is a prerequisite for high-rate CO electrolysis. The validity of this notion was demonstrated by performing CO electrolysis experiments at high current density (1 A cm-2) for several hours using PVDF as the catalyst binder.
期刊介绍:
Energy & Fuels publishes reports of research in the technical area defined by the intersection of the disciplines of chemistry and chemical engineering and the application domain of non-nuclear energy and fuels. This includes research directed at the formation of, exploration for, and production of fossil fuels and biomass; the properties and structure or molecular composition of both raw fuels and refined products; the chemistry involved in the processing and utilization of fuels; fuel cells and their applications; and the analytical and instrumental techniques used in investigations of the foregoing areas.
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