Non-invasive current collectors for improved current-density distribution during CO2 electrolysis on super-hydrophobic electrodes

Hugo-Pieter Iglesias van Montfort; Mengran Li; Erdem Irtem; Maryam Abdinejad; Yuming Wu; Santosh K. Pal; Mark Sassenburg; Davide Ripepi; Siddhartha Subramanian; Jasper Biemolt; Thomas E. Rufford; Thomas Burdyny

doi:10.1038/s41467-023-42348-6

Non-invasive current collectors for improved current-density distribution during CO₂ electrolysis on super-hydrophobic electrodes

Hugo-Pieter Iglesias van Montfort, Mengran Li, Erdem Irtem, Maryam Abdinejad, Yuming Wu, Santosh K. Pal, Mark Sassenburg, Davide Ripepi, Siddhartha Subramanian, Jasper Biemolt, Thomas E. Rufford, Thomas Burdyny^*

^*Corresponding author for this work

Research output: Contribution to journal › Article › peer-review

19 Citations (Scopus)

22 Downloads (Pure)

Abstract

Electrochemical reduction of CO₂ presents an attractive way to store renewable 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 maintain more uniform current distributions with 10-fold thinner catalyst layers while improving stability towards ethylene (≥ 30%) by approximately two-fold.

Original language	English
Article number	6579
Pages (from-to)	1-11
Number of pages	11
Journal	Nature Communications
Volume	14
DOIs	https://doi.org/10.1038/s41467-023-42348-6
Publication status	Published - 2023
Externally published	Yes

Bibliographical note

Copyright the Author(s) 2023. Version archived for private and non-commercial use with the permission of the author/s and according to publisher conditions. For further rights please contact the publisher.

Access to Document

10.1038/s41467-023-42348-6Licence: CC BY

Publisher version (open access)Final published version, 1.99 MBLicence: CC BY

Cite this

Iglesias van Montfort, H.-P., Li, M., Irtem, E., Abdinejad, M., Wu, Y., Pal, S. K., Sassenburg, M., Ripepi, D., Subramanian, S., Biemolt, J., Rufford, T. E., & Burdyny, T. (2023). Non-invasive current collectors for improved current-density distribution during CO₂ electrolysis on super-hydrophobic electrodes. Nature Communications, 14, 1-11. Article 6579. https://doi.org/10.1038/s41467-023-42348-6

@article{1fde4b05105b4c5f91a91dc1438483e0,

title = "Non-invasive current collectors for improved current-density distribution during CO2 electrolysis on super-hydrophobic electrodes",

abstract = "Electrochemical reduction of CO2 presents an attractive way to store renewable 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{\textquoteright}s), or carbon-based GDL{\textquoteright}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{\textquoteright}s. We then compare the effects of thicker catalyst layers (~500 nm) and a newly developed non-invasive current collector (NICC). The NICC can maintain more uniform current distributions with 10-fold thinner catalyst layers while improving stability towards ethylene (≥ 30%) by approximately two-fold.",

author = "{Iglesias van Montfort}, Hugo-Pieter and Mengran Li and Erdem Irtem and Maryam Abdinejad and Yuming Wu and Pal, {Santosh K.} and Mark Sassenburg and Davide Ripepi and Siddhartha Subramanian and Jasper Biemolt and Rufford, {Thomas E.} and Thomas Burdyny",

note = "Copyright the Author(s) 2023. Version archived for private and non-commercial use with the permission of the author/s and according to publisher conditions. For further rights please contact the publisher.",

year = "2023",

doi = "10.1038/s41467-023-42348-6",

language = "English",

volume = "14",

pages = "1--11",

journal = "Nature Communications",

issn = "2041-1723",

publisher = "Springer, Springer Nature",

}

Iglesias van Montfort, H-P, Li, M, Irtem, E, Abdinejad, M, Wu, Y, Pal, SK, Sassenburg, M, Ripepi, D, Subramanian, S, Biemolt, J, Rufford, TE & Burdyny, T 2023, 'Non-invasive current collectors for improved current-density distribution during CO₂ electrolysis on super-hydrophobic electrodes', Nature Communications, vol. 14, 6579, pp. 1-11. https://doi.org/10.1038/s41467-023-42348-6

TY - JOUR

T1 - Non-invasive current collectors for improved current-density distribution during CO2 electrolysis on super-hydrophobic electrodes

AU - Iglesias van Montfort, Hugo-Pieter

AU - Li, Mengran

AU - Irtem, Erdem

AU - Abdinejad, Maryam

AU - Wu, Yuming

AU - Pal, Santosh K.

AU - Sassenburg, Mark

AU - Ripepi, Davide

AU - Subramanian, Siddhartha

AU - Biemolt, Jasper

AU - Rufford, Thomas E.

AU - Burdyny, Thomas

N1 - Copyright the Author(s) 2023. Version archived for private and non-commercial use with the permission of the author/s and according to publisher conditions. For further rights please contact the publisher.

PY - 2023

Y1 - 2023

N2 - Electrochemical reduction of CO2 presents an attractive way to store renewable 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 maintain more uniform current distributions with 10-fold thinner catalyst layers while improving stability towards ethylene (≥ 30%) by approximately two-fold.

AB - Electrochemical reduction of CO2 presents an attractive way to store renewable 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 maintain more uniform current distributions with 10-fold thinner catalyst layers while improving stability towards ethylene (≥ 30%) by approximately two-fold.

UR - http://www.scopus.com/inward/record.url?scp=85174463618&partnerID=8YFLogxK

UR - http://purl.org/au-research/grants/arc/DE230100637

U2 - 10.1038/s41467-023-42348-6

DO - 10.1038/s41467-023-42348-6

M3 - Article

C2 - 37852966

SN - 2041-1723

VL - 14

SP - 1

EP - 11

JO - Nature Communications

JF - Nature Communications

M1 - 6579

ER -

Non-invasive current collectors for improved current-density distribution during CO₂ electrolysis on super-hydrophobic electrodes

Abstract

Bibliographical note

Access to Document

Other files and links

Fingerprint

Cite this