Issue 5, 2024

A novel electrochemical flow-cell for operando XAS investigations in X-ray opaque supports

Abstract

Improvement of electrochemical technologies is one of the most popular topics in the field of renewable energy. However, this process requires a deep understanding of the electrode–electrolyte interface behavior under operando conditions. X-ray absorption spectroscopy (XAS) is widely employed to characterize electrode materials, providing element-selective oxidation state and local structure. Several existing cells allow studies as close as possible to realistic operating conditions, but most of them rely on the deposition of the electrodes on conductive and X-ray transparent materials, from where the radiation impinges the sample. In this work, we present a new electrochemical flow-cell for operando XAS that can be used with X-ray opaque substrates, since the signal is effectively detected from the electrode surface, as the radiation passes through a thin layer of electrolyte (∼17 μm). The electrolyte can flow over the electrode, reducing bubble formation and avoiding strong reactant concentration gradients. We show that high-quality data can be obtained under operando conditions, thanks to the high efficiency of the cell from the hard X-ray regime down to ∼4 keV. We report as a case study the operando XAS investigation at the Fe and Ni K-edges on Ni-doped γ-Fe2O3 films, epitaxially grown on Pt substrates. The effect of the Ni content on the catalytic performances for the oxygen evolution reaction is discussed.

Graphical abstract: A novel electrochemical flow-cell for operando XAS investigations in X-ray opaque supports

Supplementary files

Article information

Article type
Paper
Submitted
28 Sep 2023
Accepted
08 Jan 2024
First published
08 Jan 2024

Phys. Chem. Chem. Phys., 2024,26, 3897-3906

A novel electrochemical flow-cell for operando XAS investigations in X-ray opaque supports

F. Paparoni, G. Alizon, A. Zitolo, S. J. Rezvani, A. Di Cicco, H. Magnan and E. Fonda, Phys. Chem. Chem. Phys., 2024, 26, 3897 DOI: 10.1039/D3CP04701F

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