Data underlying the publication: Non-invasive current collectors for improved current-density distribution during CO2 electrolysis on super-hydrophobic electrodes

doi:10.4121/2fb59b38-125b-429f-8e53-372bf8cc1291.v1
The doi above is for this specific version of this dataset, which is currently the latest. Newer versions may be published in the future. For a link that will always point to the latest version, please use
doi: 10.4121/2fb59b38-125b-429f-8e53-372bf8cc1291
Datacite citation style:
Iglesias van Montfort, Hugo-Pieter; Burdyny, Tom (2024): Data underlying the publication: Non-invasive current collectors for improved current-density distribution during CO2 electrolysis on super-hydrophobic electrodes. Version 1. 4TU.ResearchData. dataset. https://doi.org/10.4121/2fb59b38-125b-429f-8e53-372bf8cc1291.v1
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Dataset

Electrochemical reduction of CO2 presents an attractive way to store renew- able energy in chemical bonds in a potentially carbon-neutral way. However, the available electrolyzers suffer from intrinsic problems, like flooding and salt accumulation, that must be overcome to industrialize the technology. To mitigate flooding and salt precipitation issues, researchers have used super- hydrophobic electrodes based on either expanded polytetrafluoroethylene (ePTFE) gas-diffusion layers (GDL’s), or carbon-based GDL’s with added PTFE. While the PTFE backbone is highly resistant to flooding, the non-conductive nature of PTFE means that without additional current collection the catalyst layer itself is responsible for electron-dispersion, which penalizes system efficiency and stability. In this work, we present operando results that illustrate that the current distribution and electrical potential distribution is far from a uniform distribution in thin catalyst layers (~50 nm) deposited onto ePTFE GDL’s. We then compare the effects of thicker catalyst layers (~500 nm) and a newly developed non-invasive current collector (NICC). The NICC can main- tain more uniform current distributions with 10-fold thinner catalyst layers while improving stability towards ethylene (≥ 30%) by approximately two-fold.

history
  • 2024-03-28 first online, published, posted
publisher
4TU.ResearchData
format
xlsx
organizations
TU Delft, Faculty of Applied Sciences, Department of chemical engineering

DATA

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