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Main Authors: Pawelko, J., Rocquefelte, X., Tetenoire, A., Coq, D. Le, Calvez, L., Furet, E.
Format: Preprint
Published: 2026
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Online Access:https://arxiv.org/abs/2602.22989
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author Pawelko, J.
Rocquefelte, X.
Tetenoire, A.
Coq, D. Le
Calvez, L.
Furet, E.
author_facet Pawelko, J.
Rocquefelte, X.
Tetenoire, A.
Coq, D. Le
Calvez, L.
Furet, E.
contents All-solid-state lithium-ion batteries have renewed interest in high-performance solid electrolytes. Li3PS4 (Li2S-P2S5) glasses are among the most studied due to their high ionic conductivity, traditionally ascribed to rotational motion of polyhedral units facilitating Li+ migration. Using ab initio molecular dynamics, we investigate Li-ion diffusion in Li3PS4 glass, demonstrating that our structural model reproduces experimental neutron and X-ray diffraction patterns and conductivity measurements. Importantly, we identify a previously unrecognized diffusion mechanism: Li+ ions near isolated sulfur species (Sn with n = 1, 3) display significantly enhanced mobility, with atomic displacements up to 1.7 greater than those associated with bulkier polyhedral units. These results highlight the critical role of free sulfur species in promoting fast ionic transport, providing insights for the rational design of glass compositions with optimized conductivity for solid-state battery applications
format Preprint
id arxiv_https___arxiv_org_abs_2602_22989
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Mechanistic Insights into Li+ Transport Enabled by Isolated Sulfur Species in Li3PS4 Glasses
Pawelko, J.
Rocquefelte, X.
Tetenoire, A.
Coq, D. Le
Calvez, L.
Furet, E.
Materials Science
All-solid-state lithium-ion batteries have renewed interest in high-performance solid electrolytes. Li3PS4 (Li2S-P2S5) glasses are among the most studied due to their high ionic conductivity, traditionally ascribed to rotational motion of polyhedral units facilitating Li+ migration. Using ab initio molecular dynamics, we investigate Li-ion diffusion in Li3PS4 glass, demonstrating that our structural model reproduces experimental neutron and X-ray diffraction patterns and conductivity measurements. Importantly, we identify a previously unrecognized diffusion mechanism: Li+ ions near isolated sulfur species (Sn with n = 1, 3) display significantly enhanced mobility, with atomic displacements up to 1.7 greater than those associated with bulkier polyhedral units. These results highlight the critical role of free sulfur species in promoting fast ionic transport, providing insights for the rational design of glass compositions with optimized conductivity for solid-state battery applications
title Mechanistic Insights into Li+ Transport Enabled by Isolated Sulfur Species in Li3PS4 Glasses
topic Materials Science
url https://arxiv.org/abs/2602.22989