Mechanism of the electrochemical hydrogenation of graphene

Y. C. Soong; H. Li; Y. Fu; J. Tong; S. Huang; X. Zhang; E. Griffin; E. Hoenig; M. Alhashmi; Y. Li; D. Bahamon; J. Zhong; A. Summerfield; R. N. Costa Filho; C. Sevik; R. Gorbachev; E. C. Neyts; L. F. Vega; F. M. Peeters; M. Lozada-Hidalgo

doi:10.1038/s41467-025-65771-3

Mechanism of the electrochemical hydrogenation of graphene

Y. C. Soong, H. Li, Y. Fu, J. Tong, S. Huang, X. Zhang, E. Griffin, E. Hoenig, M. Alhashmi, Y. Li, D. Bahamon, J. Zhong, A. Summerfield, R. N. Costa Filho, C. Sevik, R. Gorbachev, E. C. Neyts, L. F. Vega, F. M. Peeters, M. Lozada-Hidalgo

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

Abstract

The electrochemical hydrogenation of graphene induces a robust and reversible conductor-insulator transition, of strong interest in logic-and-memory applications. However, its mechanism remains unknown. Here we show that it proceeds as a reduction reaction in which proton adsorption competes with the formation of H₂ molecules via an Eley-Rideal process. Graphene’s electrochemical hydrogenation is up to 10⁶ times faster than alternative hydrogenation methods and is fully reversible via the oxidative desorption of protons. We demonstrate that the proton reduction rate in defect-free graphene can be enhanced by an order of magnitude by the introduction of nanoscale corrugations in its lattice, and that the substitution of protons for deuterons results both in lower potentials for the hydrogenation process and in a more stable compound. Our results pave the way to investigating the chemisorption of ions in 2D materials at high electric fields, opening a new avenue to control these materials’ electronic properties.

Original language	English
Article number	10741
Number of pages	10
Journal	Nature Communications
Volume	16
Issue number	1
Early online date	28 Nov 2025
DOIs	https://doi.org/10.1038/s41467-025-65771-3
Publication status	Published - 31 Dec 2025

Data Availability Statement

All data supporting the findings of this study are available within the article, the Supplementary Information file or in the database under accession code https://zenodo.org/records/17209896.

ASJC Scopus subject areas

General Chemistry
General Biochemistry,Genetics and Molecular Biology
General
General Physics and Astronomy

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Soong, Y. C., Li, H., Fu, Y., Tong, J., Huang, S., Zhang, X., Griffin, E., Hoenig, E., Alhashmi, M., Li, Y., Bahamon, D., Zhong, J., Summerfield, A., Costa Filho, R. N., Sevik, C., Gorbachev, R., Neyts, E. C., Vega, L. F., Peeters, F. M., & Lozada-Hidalgo, M. (2025). Mechanism of the electrochemical hydrogenation of graphene. Nature Communications, 16(1), Article 10741. https://doi.org/10.1038/s41467-025-65771-3

Soong, YC, Li, H, Fu, Y, Tong, J, Huang, S, Zhang, X, Griffin, E, Hoenig, E, Alhashmi, M, Li, Y, Bahamon, D, Zhong, J, Summerfield, A, Costa Filho, RN, Sevik, C, Gorbachev, R, Neyts, EC, Vega, LF, Peeters, FM & Lozada-Hidalgo, M 2025, 'Mechanism of the electrochemical hydrogenation of graphene', Nature Communications, vol. 16, no. 1, 10741. https://doi.org/10.1038/s41467-025-65771-3

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abstract = "The electrochemical hydrogenation of graphene induces a robust and reversible conductor-insulator transition, of strong interest in logic-and-memory applications. However, its mechanism remains unknown. Here we show that it proceeds as a reduction reaction in which proton adsorption competes with the formation of H2 molecules via an Eley-Rideal process. Graphene{\textquoteright}s electrochemical hydrogenation is up to 106 times faster than alternative hydrogenation methods and is fully reversible via the oxidative desorption of protons. We demonstrate that the proton reduction rate in defect-free graphene can be enhanced by an order of magnitude by the introduction of nanoscale corrugations in its lattice, and that the substitution of protons for deuterons results both in lower potentials for the hydrogenation process and in a more stable compound. Our results pave the way to investigating the chemisorption of ions in 2D materials at high electric fields, opening a new avenue to control these materials{\textquoteright} electronic properties.",

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AU - Costa Filho, R. N.

AU - Sevik, C.

AU - Gorbachev, R.

AU - Neyts, E. C.

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Mechanism of the electrochemical hydrogenation of graphene

Abstract

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