Issue 10, 2024

Quantitative local state of charge mapping by operando electrochemical fluorescence microscopy in porous electrodes

Abstract

We introduce operando quantitative electrochemical fluorescence state of charge mapping (QEFSM), a non-invasive technique to study operating electrochemical systems along with a new design of optically transparent microfluidic redox flow cells compatible with the most demanding optical requirements. QEFSM allows quantitative mappings of the concentration of a particular oxidation state of a redox-active species within a porous electrode during its operation. In this study, we used confocal microscopy to map the fluorescence signal of the reduced form of 2,7-anthraquinone disulfonate (AQDS) in a set of multistep-chronoamperometry experiments. Calibrating these images and incorporating an analytical model of quinhydrone heterodimer formation with no free parameters, and accounting for the emission of each species involved, we determined the local molecular concentration and the state of charge (SOC) fields within a commercial porous electrode during operation. With this method, electrochemical conversion and species advection, reaction and diffusion can be monitored at heretofore unprecedented transverse and axial resolution (1 μm and 25 μm, respectively) at frame rates of 0.5 Hz, opening new routes to understanding local electrochemical processes in porous electrodes. We observed pore-scale SOC inhomogeneities appearing when the fraction of electroactive species converted in a single pass through the electrode becomes large.

Graphical abstract: Quantitative local state of charge mapping by operando electrochemical fluorescence microscopy in porous electrodes

Supplementary files

Article information

Article type
Paper
Submitted
06 Jūn. 2024
Accepted
27 Aug. 2024
First published
28 Aug. 2024
This article is Open Access
Creative Commons BY license

Energy Adv., 2024,3, 2468-2478

Quantitative local state of charge mapping by operando electrochemical fluorescence microscopy in porous electrodes

A. M. Graf, T. Cochard, K. Amini, M. S. Emanuel, S. M. Rubinstein and M. J. Aziz, Energy Adv., 2024, 3, 2468 DOI: 10.1039/D4YA00362D

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