Unified iontronic sensing for operando monitoring of physical-chemical events in lithium-ion batteries

Yu Chang; Yu Cheng; Rui Jia; Ruojiang Wang; Qing Xu; Lanqing Gong; Yike Wei; Bin Tang; Chenhui Guo; Bin Sun; Xingmin He; Xueyan Li; Lili Gong; Hong Ye; Xiaoyang Wang; Yitao Dai; Mingdong Dong; Yongbing Tang; Fan Zhang; Peng Tan; Tingrui Pan

doi:10.1093/nsr/nwaf151

Unified iontronic sensing for operando monitoring of physical-chemical events in lithium-ion batteries

Yu Chang^*, Yu Cheng, Rui Jia, Ruojiang Wang, Qing Xu, Lanqing Gong, Yike Wei, Bin Tang, Chenhui Guo, Bin Sun, Xingmin He, Xueyan Li, Lili Gong, Hong Ye, Xiaoyang Wang, Yitao Dai, Mingdong Dong, Yongbing Tang^*, Fan Zhang^*, Peng Tan^*Tingrui Pan^*

^*Corresponding author for this work

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

Abstract

Operando measurement of expansion force has become an effective way of monitoring physical-chemical events in lithium-ion batteries, of which the conventional optical means is limited by material fragility, structural incompatibility and system complexity. The utilization of flexible sensors can potentially address these challenges; however, their functionality and stability are restricted within hours in corrosive environments. Here, an in-situ unified iontronic sensing mechanism, derived from the super-capacitive electrode/electrolyte interface, is developed for expansion-force measurement in highly corrosive electrolyte environments. Specifically, it leverages the structural and material similarities between batteries and iontronic sensors to create a unified assessing device, utilizing only existing materials to produce in-situ detection. Consequently, the intelligence-incorporated architecture exhibits exceptional stability for continuous measurements over one month, enabling 400 charging/discharging cycles in a battery lifespan. Therefore, the unified iontronic sensing device, which has long-term on-board monitoring of expansion forces, offers an accurate and effective solution for the aging evaluation and safety pre-warning of lithium-ion batteries.

Original language	English
Article number	nwaf151
Journal	National Science Review
Volume	12
Issue number	6
DOIs	https://doi.org/10.1093/nsr/nwaf151
Publication status	Published - 1 Jun 2025
Externally published	Yes

Keywords

battery safety
flexible electronics
implanted sensor
iontronic
lithium-ion battery
operando sensing

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

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10.1093/nsr/nwaf151

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Chang, Y., Cheng, Y., Jia, R., Wang, R., Xu, Q., Gong, L., Wei, Y., Tang, B., Guo, C., Sun, B., He, X., Li, X., Gong, L., Ye, H., Wang, X., Dai, Y., Dong, M., Tang, Y., Zhang, F., ... Pan, T. (2025). Unified iontronic sensing for operando monitoring of physical-chemical events in lithium-ion batteries. National Science Review, 12(6), Article nwaf151. https://doi.org/10.1093/nsr/nwaf151

@article{7fbe8739add84e42b66962491d3c77a2,

title = "Unified iontronic sensing for operando monitoring of physical-chemical events in lithium-ion batteries",

abstract = "Operando measurement of expansion force has become an effective way of monitoring physical-chemical events in lithium-ion batteries, of which the conventional optical means is limited by material fragility, structural incompatibility and system complexity. The utilization of flexible sensors can potentially address these challenges; however, their functionality and stability are restricted within hours in corrosive environments. Here, an in-situ unified iontronic sensing mechanism, derived from the super-capacitive electrode/electrolyte interface, is developed for expansion-force measurement in highly corrosive electrolyte environments. Specifically, it leverages the structural and material similarities between batteries and iontronic sensors to create a unified assessing device, utilizing only existing materials to produce in-situ detection. Consequently, the intelligence-incorporated architecture exhibits exceptional stability for continuous measurements over one month, enabling 400 charging/discharging cycles in a battery lifespan. Therefore, the unified iontronic sensing device, which has long-term on-board monitoring of expansion forces, offers an accurate and effective solution for the aging evaluation and safety pre-warning of lithium-ion batteries.",

keywords = "battery safety, flexible electronics, implanted sensor, iontronic, lithium-ion battery, operando sensing",

author = "Yu Chang and Yu Cheng and Rui Jia and Ruojiang Wang and Qing Xu and Lanqing Gong and Yike Wei and Bin Tang and Chenhui Guo and Bin Sun and Xingmin He and Xueyan Li and Lili Gong and Hong Ye and Xiaoyang Wang and Yitao Dai and Mingdong Dong and Yongbing Tang and Fan Zhang and Peng Tan and Tingrui Pan",

note = "Publisher Copyright: {\textcopyright} The Author(s) 2025. Published by Oxford University Press on behalf of China Science Publishing \& Media Ltd.",

year = "2025",

month = jun,

day = "1",

doi = "10.1093/nsr/nwaf151",

language = "English",

volume = "12",

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Chang, Y, Cheng, Y, Jia, R, Wang, R, Xu, Q, Gong, L, Wei, Y, Tang, B, Guo, C, Sun, B, He, X, Li, X, Gong, L, Ye, H, Wang, X, Dai, Y, Dong, M, Tang, Y, Zhang, F, Tan, P & Pan, T 2025, 'Unified iontronic sensing for operando monitoring of physical-chemical events in lithium-ion batteries', National Science Review, vol. 12, no. 6, nwaf151. https://doi.org/10.1093/nsr/nwaf151

TY - JOUR

T1 - Unified iontronic sensing for operando monitoring of physical-chemical events in lithium-ion batteries

AU - Chang, Yu

AU - Cheng, Yu

AU - Jia, Rui

AU - Wang, Ruojiang

AU - Xu, Qing

AU - Gong, Lanqing

AU - Wei, Yike

AU - Tang, Bin

AU - Guo, Chenhui

AU - Sun, Bin

AU - He, Xingmin

AU - Li, Xueyan

AU - Gong, Lili

AU - Ye, Hong

AU - Wang, Xiaoyang

AU - Dai, Yitao

AU - Dong, Mingdong

AU - Tang, Yongbing

AU - Zhang, Fan

AU - Tan, Peng

AU - Pan, Tingrui

PY - 2025/6/1

Y1 - 2025/6/1

N2 - Operando measurement of expansion force has become an effective way of monitoring physical-chemical events in lithium-ion batteries, of which the conventional optical means is limited by material fragility, structural incompatibility and system complexity. The utilization of flexible sensors can potentially address these challenges; however, their functionality and stability are restricted within hours in corrosive environments. Here, an in-situ unified iontronic sensing mechanism, derived from the super-capacitive electrode/electrolyte interface, is developed for expansion-force measurement in highly corrosive electrolyte environments. Specifically, it leverages the structural and material similarities between batteries and iontronic sensors to create a unified assessing device, utilizing only existing materials to produce in-situ detection. Consequently, the intelligence-incorporated architecture exhibits exceptional stability for continuous measurements over one month, enabling 400 charging/discharging cycles in a battery lifespan. Therefore, the unified iontronic sensing device, which has long-term on-board monitoring of expansion forces, offers an accurate and effective solution for the aging evaluation and safety pre-warning of lithium-ion batteries.

AB - Operando measurement of expansion force has become an effective way of monitoring physical-chemical events in lithium-ion batteries, of which the conventional optical means is limited by material fragility, structural incompatibility and system complexity. The utilization of flexible sensors can potentially address these challenges; however, their functionality and stability are restricted within hours in corrosive environments. Here, an in-situ unified iontronic sensing mechanism, derived from the super-capacitive electrode/electrolyte interface, is developed for expansion-force measurement in highly corrosive electrolyte environments. Specifically, it leverages the structural and material similarities between batteries and iontronic sensors to create a unified assessing device, utilizing only existing materials to produce in-situ detection. Consequently, the intelligence-incorporated architecture exhibits exceptional stability for continuous measurements over one month, enabling 400 charging/discharging cycles in a battery lifespan. Therefore, the unified iontronic sensing device, which has long-term on-board monitoring of expansion forces, offers an accurate and effective solution for the aging evaluation and safety pre-warning of lithium-ion batteries.

KW - battery safety

KW - flexible electronics

KW - implanted sensor

KW - iontronic

KW - lithium-ion battery

KW - operando sensing

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U2 - 10.1093/nsr/nwaf151

DO - 10.1093/nsr/nwaf151

M3 - Article

AN - SCOPUS:105007341760

SN - 2095-5138

VL - 12

JO - National Science Review

JF - National Science Review

IS - 6

M1 - nwaf151

ER -

Unified iontronic sensing for operando monitoring of physical-chemical events in lithium-ion batteries

Abstract

Keywords

UN SDGs

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