Transient Au–Cl adlayers modulate the surface chemistry of gold nanoparticles during redox reactions

Sarah May Sibug-Torres; Marika Niihori; Elle Wyatt; Rakesh Arul; Nicolas Spiesshofer; Tabitha Jones; Duncan Graham; Bart De Nijs; Oren A. Scherman; Reshma R. Rao; Mary P. Ryan; Alex Squires; Chris Savory; David Scanlon; Abdalghani Daaoub; Sara Sangtarash; Hatef Sadeghi; Jeremy Baumberg

doi:10.1038/s41557-025-01989-4

Transient Au–Cl adlayers modulate the surface chemistry of gold nanoparticles during redox reactions

Sarah May Sibug-Torres
, Marika Niihori
, Elle Wyatt
, Rakesh Arul
, Nicolas Spiesshofer
, Tabitha Jones
, Duncan Graham
, Bart De Nijs
, Oren A. Scherman
, Reshma R. Rao
, Mary P. Ryan
, Alex Squires
, Chris Savory
, David Scanlon
, Abdalghani Daaoub
, Sara Sangtarash
, Hatef Sadeghi
, Jeremy Baumberg^*

^*Corresponding author for this work

Chemistry

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

Abstract

Controlling surface chemistry at the nanoscale is essential for stabilizing structure and tuning function in plasmonic, catalytic and sensing systems, where even trace ligands or ions can reshape surface charge and reactivity. However, probing such dynamic interfaces under operando conditions remains challenging, limiting efforts to engineer nanomaterials with precision. Here, using in situ surface-enhanced Raman spectroscopy, we identify a transient Au–Cl adlayer that forms during electrochemical cycling at gold interfaces. The adlayer exhibits significant charge transfer between gold and chlorine, generating an outward-facing dipole that polarizes neighbouring atoms and modulates the local potential. This dipole stabilizes nanogap interfaces and directs oriented ligand rebinding, enabling reversible reconstruction of subnanometre architectures. It also alters interfacial charge distributions and mediates electron transfer between gold oxidation states, acting as a redox-active intermediate. These findings show how transient surface species shape nanoscale reactivity and stability, offering strategies for designing catalysts, sensors and nanomaterials.

Original language	English
Number of pages	20
Journal	Nature Chemistry
Early online date	13 Nov 2025
DOIs	https://doi.org/10.1038/s41557-025-01989-4
Publication status	E-pub ahead of print - 13 Nov 2025

Keywords

cucurbit[n]urils
gold facets
electrochemical regeneration
nanogap

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SibugTorresSM2025TransientFinal published version, 12.8 MBLicence: Creative Commons: Attribution (CC BY)

Baskerville 2.0: Enhanced Provision for High End and On-Demand Users
Styles, I. (Principal Investigator)
Engineering & Physical Science Research Council
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Project: Research Councils
Baskerville: a national accelerated compute resource
Cai, B. (Co-Investigator) & Morris, A. (Principal Investigator)
Engineering & Physical Science Research Council, Lenovo UK Limited
13/10/20 → 31/03/25
Project: Research Councils

Cite this

Sibug-Torres, S. M., Niihori, M., Wyatt, E., Arul, R., Spiesshofer, N., Jones, T., Graham, D., De Nijs, B., Scherman, O. A., Rao, R. R., Ryan, M. P., Squires, A., Savory, C., Scanlon, D., Daaoub, A., Sangtarash, S., Sadeghi , H., & Baumberg, J. (2025). Transient Au–Cl adlayers modulate the surface chemistry of gold nanoparticles during redox reactions. Nature Chemistry. Advance online publication. https://doi.org/10.1038/s41557-025-01989-4

@article{1819ee6f923946eda597de6226684982,

title = "Transient Au–Cl adlayers modulate the surface chemistry of gold nanoparticles during redox reactions",

abstract = "Controlling surface chemistry at the nanoscale is essential for stabilizing structure and tuning function in plasmonic, catalytic and sensing systems, where even trace ligands or ions can reshape surface charge and reactivity. However, probing such dynamic interfaces under operando conditions remains challenging, limiting efforts to engineer nanomaterials with precision. Here, using in situ surface-enhanced Raman spectroscopy, we identify a transient Au–Cl adlayer that forms during electrochemical cycling at gold interfaces. The adlayer exhibits significant charge transfer between gold and chlorine, generating an outward-facing dipole that polarizes neighbouring atoms and modulates the local potential. This dipole stabilizes nanogap interfaces and directs oriented ligand rebinding, enabling reversible reconstruction of subnanometre architectures. It also alters interfacial charge distributions and mediates electron transfer between gold oxidation states, acting as a redox-active intermediate. These findings show how transient surface species shape nanoscale reactivity and stability, offering strategies for designing catalysts, sensors and nanomaterials.",

keywords = "cucurbit[n]urils, gold facets, electrochemical regeneration, nanogap",

author = "Sibug-Torres, \{Sarah May\} and Marika Niihori and Elle Wyatt and Rakesh Arul and Nicolas Spiesshofer and Tabitha Jones and Duncan Graham and \{De Nijs\}, Bart and Scherman, \{Oren A.\} and Rao, \{Reshma R.\} and Ryan, \{Mary P.\} and Alex Squires and Chris Savory and David Scanlon and Abdalghani Daaoub and Sara Sangtarash and Hatef Sadeghi and Jeremy Baumberg",

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doi = "10.1038/s41557-025-01989-4",

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Sibug-Torres, SM, Niihori, M, Wyatt, E, Arul, R, Spiesshofer, N, Jones, T, Graham, D, De Nijs, B, Scherman, OA, Rao, RR, Ryan, MP, Squires, A, Savory, C, Scanlon, D, Daaoub, A, Sangtarash, S, Sadeghi , H & Baumberg, J 2025, 'Transient Au–Cl adlayers modulate the surface chemistry of gold nanoparticles during redox reactions', Nature Chemistry. https://doi.org/10.1038/s41557-025-01989-4

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T1 - Transient Au–Cl adlayers modulate the surface chemistry of gold nanoparticles during redox reactions

AU - Sibug-Torres, Sarah May

AU - Niihori, Marika

AU - Wyatt, Elle

AU - Arul, Rakesh

AU - Spiesshofer, Nicolas

AU - Jones, Tabitha

AU - Graham, Duncan

AU - De Nijs, Bart

AU - Scherman, Oren A.

AU - Rao, Reshma R.

AU - Ryan, Mary P.

AU - Squires, Alex

AU - Savory, Chris

AU - Scanlon, David

AU - Daaoub, Abdalghani

AU - Sangtarash, Sara

AU - Sadeghi , Hatef

AU - Baumberg, Jeremy

PY - 2025/11/13

Y1 - 2025/11/13

N2 - Controlling surface chemistry at the nanoscale is essential for stabilizing structure and tuning function in plasmonic, catalytic and sensing systems, where even trace ligands or ions can reshape surface charge and reactivity. However, probing such dynamic interfaces under operando conditions remains challenging, limiting efforts to engineer nanomaterials with precision. Here, using in situ surface-enhanced Raman spectroscopy, we identify a transient Au–Cl adlayer that forms during electrochemical cycling at gold interfaces. The adlayer exhibits significant charge transfer between gold and chlorine, generating an outward-facing dipole that polarizes neighbouring atoms and modulates the local potential. This dipole stabilizes nanogap interfaces and directs oriented ligand rebinding, enabling reversible reconstruction of subnanometre architectures. It also alters interfacial charge distributions and mediates electron transfer between gold oxidation states, acting as a redox-active intermediate. These findings show how transient surface species shape nanoscale reactivity and stability, offering strategies for designing catalysts, sensors and nanomaterials.

AB - Controlling surface chemistry at the nanoscale is essential for stabilizing structure and tuning function in plasmonic, catalytic and sensing systems, where even trace ligands or ions can reshape surface charge and reactivity. However, probing such dynamic interfaces under operando conditions remains challenging, limiting efforts to engineer nanomaterials with precision. Here, using in situ surface-enhanced Raman spectroscopy, we identify a transient Au–Cl adlayer that forms during electrochemical cycling at gold interfaces. The adlayer exhibits significant charge transfer between gold and chlorine, generating an outward-facing dipole that polarizes neighbouring atoms and modulates the local potential. This dipole stabilizes nanogap interfaces and directs oriented ligand rebinding, enabling reversible reconstruction of subnanometre architectures. It also alters interfacial charge distributions and mediates electron transfer between gold oxidation states, acting as a redox-active intermediate. These findings show how transient surface species shape nanoscale reactivity and stability, offering strategies for designing catalysts, sensors and nanomaterials.

KW - cucurbit[n]urils

KW - gold facets

KW - electrochemical regeneration

KW - nanogap

U2 - 10.1038/s41557-025-01989-4

DO - 10.1038/s41557-025-01989-4

M3 - Article

SN - 1755-4330

JO - Nature Chemistry

JF - Nature Chemistry

ER -

Transient Au–Cl adlayers modulate the surface chemistry of gold nanoparticles during redox reactions

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Keywords

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Baskerville 2.0: Enhanced Provision for High End and On-Demand Users

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