Issue 3, 2024

Multi-spectroscopic study of electrochemically-formed oxide-derived gold electrodes

Abstract

Oxide-derived metals are produced by reducing an oxide precursor. These materials, including gold, have shown improved catalytic performance over many native metals. The origin of this improvement for gold is not yet understood. In this study, operando non-resonant sum frequency generation (SFG) and ex situ high-pressure X-ray photoelectron spectroscopy (HP-XPS) have been employed to investigate electrochemically-formed oxide-derived gold (OD-Au) from polycrystalline gold surfaces. A range of different oxidizing conditions were used to form OD-Au in acidic aqueous medium (H3PO4, pH = 1). Our electrochemical data after OD-Au is generated suggest that the surface is metallic gold, however SFG signal variations indicate the presence of subsurface gold oxide remnants between the metallic gold surface layer and bulk gold. The HP-XPS results suggest that this subsurface gold oxide could be in the form of Au2O3 or Au(OH)3. Furthermore, the SFG measurements show that with reducing electrochemical treatments the original gold metallic state can be restored, meaning the subsurface gold oxide is released. This work demonstrates that remnants of gold oxide persist beneath the topmost gold layer when the OD-Au is created, potentially facilitating the understanding of the improved catalytic properties of OD-Au.

Graphical abstract: Multi-spectroscopic study of electrochemically-formed oxide-derived gold electrodes

Supplementary files

Article information

Article type
Paper
Submitted
21 Aug 2023
Accepted
12 Dec 2023
First published
12 Dec 2023
This article is Open Access
Creative Commons BY-NC license

Phys. Chem. Chem. Phys., 2024,26, 2332-2340

Multi-spectroscopic study of electrochemically-formed oxide-derived gold electrodes

S. B. Bibi, A. M. El-Zohry, B. Davies, V. Grigorev, C. M. Goodwin, P. Lömker, A. Holm, H. Ali-Löytty, F. Garcia-Martinez, C. Schlueter, M. Soldemo, S. Koroidov and T. Hansson, Phys. Chem. Chem. Phys., 2024, 26, 2332 DOI: 10.1039/D3CP04009G

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