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Spatio-temporal electrowetting and reaction monitoring in microfluidic gas diffusion electrode elucidates mass transport limitations

Brosch, Sebastian ; Wiesner, Florian ; Decker, Alexandra ; Linkhorst, John ; Wessling, Matthias (2024)
Spatio-temporal electrowetting and reaction monitoring in microfluidic gas diffusion electrode elucidates mass transport limitations.
In: Small : nano micro, 20 (29)
doi: 10.1002/smll.202310427
Article, Bibliographie

Abstract

The use of gas diffusion electrodes (GDEs) enables efficient electrochemical CO2 reduction and may be a viable technology in CO2 utilization after carbon capture. Understanding the spatio-temporal phenomena at the triple-phase boundary formed inside GDEs remains a challenge; yet it is critical to design and optimize industrial electrodes for gas-fed electrolyzers. Thus far, transport and reaction phenomena are not yet fully understood at the microscale, among other factors, due to a lack of experimental analysis methods for porous electrodes under operating conditions. In this work, a realistic microfluidic GDE surrogate is presented. Combined with fluorescence lifetime imaging microscopy (FLIM), the methodology allows monitoring of wetting and local pH, representing the dynamic (in)stability of the triple phase boundary in operando. Upon charging the electrode, immediate wetting leads to an initial flooding of the catalyst layer, followed by spatially oscillating pH changes. The micromodel presented gives an experimental insight into transport phenomena within porous electrodes, which is so far difficult to achieve. The methodology and proof of the spatio-temporal pH and wetting oscillations open new opportunities to further comprehend the relationship between gas diffusion electrode properties and electrical currents originating at a given surface potential.

Item Type: Article
Erschienen: 2024
Creators: Brosch, Sebastian ; Wiesner, Florian ; Decker, Alexandra ; Linkhorst, John ; Wessling, Matthias
Type of entry: Bibliographie
Title: Spatio-temporal electrowetting and reaction monitoring in microfluidic gas diffusion electrode elucidates mass transport limitations
Language: English
Date: February 2024
Publisher: Wiley-VCH
Journal or Publication Title: Small : nano micro
Volume of the journal: 20
Issue Number: 29
DOI: 10.1002/smll.202310427
Abstract:

The use of gas diffusion electrodes (GDEs) enables efficient electrochemical CO2 reduction and may be a viable technology in CO2 utilization after carbon capture. Understanding the spatio-temporal phenomena at the triple-phase boundary formed inside GDEs remains a challenge; yet it is critical to design and optimize industrial electrodes for gas-fed electrolyzers. Thus far, transport and reaction phenomena are not yet fully understood at the microscale, among other factors, due to a lack of experimental analysis methods for porous electrodes under operating conditions. In this work, a realistic microfluidic GDE surrogate is presented. Combined with fluorescence lifetime imaging microscopy (FLIM), the methodology allows monitoring of wetting and local pH, representing the dynamic (in)stability of the triple phase boundary in operando. Upon charging the electrode, immediate wetting leads to an initial flooding of the catalyst layer, followed by spatially oscillating pH changes. The micromodel presented gives an experimental insight into transport phenomena within porous electrodes, which is so far difficult to achieve. The methodology and proof of the spatio-temporal pH and wetting oscillations open new opportunities to further comprehend the relationship between gas diffusion electrode properties and electrical currents originating at a given surface potential.

Uncontrolled Keywords: CO2 reduction, FLIM, gas diffusion electrode, microfluidics, triple-phase-boundary
Identification Number: Artikel-ID: 2310427
Divisions: 16 Department of Mechanical Engineering
16 Department of Mechanical Engineering > Chair for Process Engineering of Electrochemical Systems
Date Deposited: 24 Jul 2024 07:58
Last Modified: 24 Jul 2024 11:50
PPN: 520115252
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