Journal article

Controlling Electrode–Electrolyte Interactions to Enhance Capacitance

Abstract:: Understanding how ions interact with electrode surfaces at the molecular level is essential for improving the performance of energy storage devices and electrocatalysts. However, progress has been limited by the structural disorder and poorly defined surface chemistries of conventional carbon-based electrodes. In this work, we use layered metal–organic frameworks (MOFs) as model systems to investigate how different functional groups influence electric double-layer capacitance. We find that electrodes with deprotonated M–O and M–S groups exhibit significantly enhanced capacities with alkali metal cations, most notably Li+, compared to tetraethylammonium (TEA+), while no enhancement is observed for MOFs with protonated M–NH groups. The largest capacity increase is seen for MOF electrodes with metal–hydroxy linkages paired with Li+ electrolytes, which we attribute to strong Li–O interactions and improved charge screening. This mechanism is supported by solid-state nuclear magnetic resonance spectroscopy experiments and molecular simulations, which reveal specific Li+ binding at oxygen-rich sites, while operando X-ray techniques rule out cation intercalation as a contributing factor. Overall, these results highlight a chemically tunable strategy for enhancing charge storage in porous electrodes and offer new insights into how surface functionality impacts electric double-layer behavior.

Publication status:: Published

Peer review status:: Peer reviewed

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APA Style

Gittins, J. W., Balhatchet, C. J., Hill, J., Trisukhon, T., Seyffertitz, M., Shin, S., Khakre, Y., Ge, K., Kress, T., Marinescu, S. C., Walsh, A., Paris, O., Seymour, I. D., & Forse, A. C. (2026). Controlling Electrode–Electrolyte Interactions to Enhance Capacitance. Journal of the American Chemical Society, 148(15), 15694–15706.

MLA Style

Gittins, JW, et al. “Controlling Electrode–Electrolyte Interactions to Enhance Capacitance.” Journal of the American Chemical Society, vol. 148, no. 15, 2026, pp. 15694–706.

Chicago Style

Gittins, JW, CJ Balhatchet, J Hill, et al. 2026. “Controlling Electrode–Electrolyte Interactions to Enhance Capacitance.” Journal of the American Chemical Society 148 (15): 15694–706.
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Publisher copy:: 10.1021/jacs.5c20988

Authors

+ Gittins, JW More by this author

Role:: Author

+ Balhatchet, CJ More by this author

Role:: Author

+ Hill, J More by this author

Institution:: University of Oxford
Division:: MPLS
Department:: Chemistry
Sub department:: Chemistry
Role:: Author
ORCID:: 0009-0001-4094-1345

+ Trisukhon, T More by this author

Role:: Author

+ Seyffertitz, M More by this author

Role:: Author

More authors...

+ Engineering and Physical Sciences Research Council (EPSRC) More from this funder

Funder identifier:: 10.13039/501100000266
Grant:: EP/X042693/1

+ Isaac Newton Trust More from this funder

Funder identifier:: https://ror.org/02gn6ta77
Grant:: G101121

+ Diamond Light Source More from this funder

Funder identifier:: https://ror.org/05etxs293
Grant:: CY34243

+ Division of Materials Research More from this funder

Funder identifier:: https://ror.org/01pc7k308
Grant:: 2004868

+ UK Research and Innovation (UKRI) More from this funder

Grant:: MR/T043024/1

More funders...

Publisher:: American Chemical Society
Journal:: Journal of the American Chemical Society More from this journal
Volume:: 148
Issue:: 15
Pages:: 15694-15706
Publication date:: 2026-04-13
Acceptance date:: 2026-03-30
DOI:: 10.1021/jacs.5c20988
EISSN:: 1520-5126
ISSN:: 0002-7863

Language:: English
Keywords:: Electrolyte

Electrode

Capacitance

Supercapacitor

Intercalation (chemistry)

Materials science

Protonation

Chemical physics

Nanotechnology

Chemistry

Inorganic chemistry

Chemical engineering

Ion

Physical chemistry

Organic chemistry
Source identifiers:: 3978126
Deposit date:: 2026-04-23
ARK identifier:: ark:/29072/ora_1471fa64aea0494f80726b21959b8660

Terms of use

Copyright date:: 2026

Licence:: CC Attribution (CC BY)

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