Journal article

Lithium antiperovskite-derived glass solid electrolytes

Abstract:: In this paper, we report the synthesis of Li₂OHX (X = Br, Cl)-based glasses. These glasses were found to be challenging to synthesize, requiring extreme cooling rates achievable only by a twin-roll quench process. As has been speculated for antiperovskite-derived glasses, indications of improved lithium-ion dynamics are observed. Notably, spin–lattice relaxation nuclear magnetic resonance spectroscopy reveals a higher hopping frequency and significantly lower activation energy for Li₂OHBr glasses (0.29 eV) compared to the crystalline Li₂OHBr (0.39 eV). This may be attributable to the increased free volume in the glass samples (ρ_glass/ρ_cryst = 0.83) and a reduced ionic interaction of lithium ions with the glass structure. Despite these promising findings, the glasses were found to be unstable under pressure and crystallized in attempts to produce bulk samples for impedance measurements.

Publication status:: Published

Peer review status:: Peer reviewed

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APA Style

Milan, E., Rees, G. J., Phillips, A., Cano, C., Wei, Y., Guo, H., Feller, S., & Pasta, M. (2025). Lithium antiperovskite-derived glass solid electrolytes. ACS Materials Letters, 7(4), 1187–1194.

MLA Style

Milan, E, et al. “Lithium Antiperovskite-Derived Glass Solid Electrolytes.” ACS Materials Letters, vol. 7, no. 4, 2025, pp. 1187–94.

Chicago Style

Milan, E, GJ Rees, A Phillips, et al. 2025. “Lithium Antiperovskite-Derived Glass Solid Electrolytes.” ACS Materials Letters 7 (4): 1187–94.
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Files:: Milan_et_al_2025_Lithium_antiperovskite-derived_glass.pdf

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Publisher copy:: 10.1021/acsmaterialslett.4c02578

Authors

+ Milan, E More by this author

Institution:: University of Oxford
Division:: MPLS
Department:: Materials
Role:: Author

+ Rees, GJ More by this author

Institution:: University of Oxford
Division:: MPLS
Department:: Materials
Role:: Author

+ Phillips, A More by this author

Role:: Author

+ Cano, C More by this author

Role:: Author

+ Wei, Y More by this author

Role:: Author

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+ Engineering and Physical Sciences Research Council More from this funder

Funder identifier:: https://ror.org/0439y7842
Grant:: EP/R010145/1

Publisher:: American Chemical Society
Journal:: ACS Materials Letters More from this journal
Volume:: 7
Issue:: 4
Pages:: 1187-1194
Publication date:: 2025-02-25
Acceptance date:: 2025-02-18
DOI:: 10.1021/acsmaterialslett.4c02578
EISSN:: 2639-4979

Language:: English
Keywords:: amorphous materials

glass transition

ionic conductivity

lithium

materials
Pubs id:: 2094238
Local pid:: pubs:2094238
Deposit date:: 2025-03-30
ARK identifier:: ark:/29072/ora_ba643977ad1744d383e6099d9ee1ce66

Terms of use

Copyright holder:: Milan et al.
Copyright date:: 2025
Rights statement:: Copyright © 2025 The Authors. Published by American Chemical Society. This publication is licensed under CC-BY 4.0 .

Licence:: CC Attribution (CC BY)

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