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Main Authors: Hu, Yonggang, Liao, Yiqing, Yang, Lufeng, Zhang, Ke, Peng, Yufan, Tang, Shijun, Wang, Shengxiang, Ding, Meifang, Wu, Jiahao, Lin, Jianrong, Liang, Jinding, Wei, Yimin, Jin, Yanting, Gong, Zhengliang, Senyshyn, Anatoliy, Chen, Jie, Yang, Yong
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2510.12055
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author Hu, Yonggang
Liao, Yiqing
Yang, Lufeng
Zhang, Ke
Peng, Yufan
Tang, Shijun
Wang, Shengxiang
Ding, Meifang
Wu, Jiahao
Lin, Jianrong
Liang, Jinding
Wei, Yimin
Jin, Yanting
Gong, Zhengliang
Senyshyn, Anatoliy
Chen, Jie
Yang, Yong
author_facet Hu, Yonggang
Liao, Yiqing
Yang, Lufeng
Zhang, Ke
Peng, Yufan
Tang, Shijun
Wang, Shengxiang
Ding, Meifang
Wu, Jiahao
Lin, Jianrong
Liang, Jinding
Wei, Yimin
Jin, Yanting
Gong, Zhengliang
Senyshyn, Anatoliy
Chen, Jie
Yang, Yong
contents Non-destructive characterization of lithium-ion batteries provides critical insights for optimizing performance and lifespan while preserving structural integrity. Optimizing electrolyte design in commercial LIBs requires consideration of composition, electrolyte-to-capacity ratio, spatial distribution, and associated degradation pathways. However, existing non-destructive methods for studying electrolyte infiltration, distribution, and degradation in LIBs lack the spatiotemporal resolution required for precise observation and quantification of the electrolyte. In this study, we employ neutron imaging with sufficient spatial resolution ~150 um and large field of view 20x20 cm2 to quantitatively resolve the electrolyte inventory and distribution within LiFePO4/graphite pouch cells under high-temperature accelerated aging. Quantitative standard curves based on neutron transmission attenuation reveal a clear electrolyte dry-out threshold at 3.18 g Ah-1 and the two stages evolutions of EI during cell aging were quantified. By integrating non-destructive electrochemical diagnostics, accelerated graphite material loss and liquid phase Li+ diffusion degradation is observed during pore-drying. Further analysis, including operando cyclic aging, reveals that the neutron transmission below the saturation reference is due to the enrichment of hydrogen nuclei within the solid-electrolyte interphase. Assumed pore-drying does not occur, the SEI signal of the electrodes can be quantitatively decoupled during ageing. Combined analyses with NI, TOF-SIMS, and SEM reveal that high EI cells exhibit uniform SEI growth and reduced degradation, while low EI cells show uneven SEI formation, accelerating capacity loss. This study unveils a dynamic electrolyte infiltration-consumption-dry-out process in LIBs, offering non-destructive and quantitative insights to guide sustainable and durable battery development.
format Preprint
id arxiv_https___arxiv_org_abs_2510_12055
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Quantification of Electrolyte Degradation in Lithium-ion Batteries with Neutron Imaging Techniques
Hu, Yonggang
Liao, Yiqing
Yang, Lufeng
Zhang, Ke
Peng, Yufan
Tang, Shijun
Wang, Shengxiang
Ding, Meifang
Wu, Jiahao
Lin, Jianrong
Liang, Jinding
Wei, Yimin
Jin, Yanting
Gong, Zhengliang
Senyshyn, Anatoliy
Chen, Jie
Yang, Yong
Applied Physics
Materials Science
High Energy Physics - Experiment
Non-destructive characterization of lithium-ion batteries provides critical insights for optimizing performance and lifespan while preserving structural integrity. Optimizing electrolyte design in commercial LIBs requires consideration of composition, electrolyte-to-capacity ratio, spatial distribution, and associated degradation pathways. However, existing non-destructive methods for studying electrolyte infiltration, distribution, and degradation in LIBs lack the spatiotemporal resolution required for precise observation and quantification of the electrolyte. In this study, we employ neutron imaging with sufficient spatial resolution ~150 um and large field of view 20x20 cm2 to quantitatively resolve the electrolyte inventory and distribution within LiFePO4/graphite pouch cells under high-temperature accelerated aging. Quantitative standard curves based on neutron transmission attenuation reveal a clear electrolyte dry-out threshold at 3.18 g Ah-1 and the two stages evolutions of EI during cell aging were quantified. By integrating non-destructive electrochemical diagnostics, accelerated graphite material loss and liquid phase Li+ diffusion degradation is observed during pore-drying. Further analysis, including operando cyclic aging, reveals that the neutron transmission below the saturation reference is due to the enrichment of hydrogen nuclei within the solid-electrolyte interphase. Assumed pore-drying does not occur, the SEI signal of the electrodes can be quantitatively decoupled during ageing. Combined analyses with NI, TOF-SIMS, and SEM reveal that high EI cells exhibit uniform SEI growth and reduced degradation, while low EI cells show uneven SEI formation, accelerating capacity loss. This study unveils a dynamic electrolyte infiltration-consumption-dry-out process in LIBs, offering non-destructive and quantitative insights to guide sustainable and durable battery development.
title Quantification of Electrolyte Degradation in Lithium-ion Batteries with Neutron Imaging Techniques
topic Applied Physics
Materials Science
High Energy Physics - Experiment
url https://arxiv.org/abs/2510.12055