Electrochemical Modeling of Fast Charging in Batteries

Xudong Duan; Dayong Hu; Weiheng Chen; Jiani Li; Lubing Wang; Shuguo Sun; Jun Xu

doi:10.1002/aenm.202400710

Electrochemical Modeling of Fast Charging in Batteries

Xudong Duan
, Dayong Hu
, Weiheng Chen
, Jiani Li
, Lubing Wang
, Shuguo Sun
, Jun Xu^*

^*此作品的通讯作者

交通科学与工程学院

Beihang University
Aircraft.Engine Integrated System Safety Beijing Key Laboratory
Ningbo University of Technology
University of North Carolina at Charlotte
Ningbo University
University of Delaware

科研成果: 期刊稿件 › 文章 › 同行评审

26 引用（Scopus）

摘要

The acceleration of fast charging capabilities has emerged as a pivotal objective within the realms of the battery, electric vehicle, and energy storage sectors. However, the classical electrochemical models are not able to describe voltages of the cell (U_cell), anode (U_a), and cathode (U_c) at high C-rates. Herein, U_cell, U_a, and U_c are experimentally obtained under various C-rates (0.1–2C) and identified the charge transfer resistance of the cathode (R_CT,c) as the primary rate-limiting factor. Thus, the anode is established as a multi-scale coupling model with Fick's law and phase separation model applied, to discuss their effect on U_a and Li-ion concentration prediction. 2D reconstruction structures for the cathode is established with R_CT,c effect considered. Finally, the U_a, U_c, and U_cell are successfully predicted at different C-rates. Results propose an accurate and versatile electrochemical model and highlight the importance of considering limiting factors in electrochemical modeling for fast charging.

源语言	英语
文章编号	2400710
期刊	Advanced Energy Materials
卷	14
期	26
DOI	https://doi.org/10.1002/aenm.202400710
出版状态	已出版 - 12 7月 2024

联合国可持续发展目标

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可持续发展目标 7 经济适用的清洁能源

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10.1002/aenm.202400710

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引用此

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title = "Electrochemical Modeling of Fast Charging in Batteries",

abstract = "The acceleration of fast charging capabilities has emerged as a pivotal objective within the realms of the battery, electric vehicle, and energy storage sectors. However, the classical electrochemical models are not able to describe voltages of the cell (Ucell), anode (Ua), and cathode (Uc) at high C-rates. Herein, Ucell, Ua, and Uc are experimentally obtained under various C-rates (0.1–2C) and identified the charge transfer resistance of the cathode (RCT,c) as the primary rate-limiting factor. Thus, the anode is established as a multi-scale coupling model with Fick's law and phase separation model applied, to discuss their effect on Ua and Li-ion concentration prediction. 2D reconstruction structures for the cathode is established with RCT,c effect considered. Finally, the Ua, Uc, and Ucell are successfully predicted at different C-rates. Results propose an accurate and versatile electrochemical model and highlight the importance of considering limiting factors in electrochemical modeling for fast charging.",

keywords = "charge transfer resistance, electrochemical model, fast charging, lithium-ion battery, phase separation",

author = "Xudong Duan and Dayong Hu and Weiheng Chen and Jiani Li and Lubing Wang and Shuguo Sun and Jun Xu",

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T1 - Electrochemical Modeling of Fast Charging in Batteries

AU - Duan, Xudong

AU - Hu, Dayong

AU - Chen, Weiheng

AU - Li, Jiani

AU - Wang, Lubing

AU - Sun, Shuguo

AU - Xu, Jun

PY - 2024/7/12

Y1 - 2024/7/12

N2 - The acceleration of fast charging capabilities has emerged as a pivotal objective within the realms of the battery, electric vehicle, and energy storage sectors. However, the classical electrochemical models are not able to describe voltages of the cell (Ucell), anode (Ua), and cathode (Uc) at high C-rates. Herein, Ucell, Ua, and Uc are experimentally obtained under various C-rates (0.1–2C) and identified the charge transfer resistance of the cathode (RCT,c) as the primary rate-limiting factor. Thus, the anode is established as a multi-scale coupling model with Fick's law and phase separation model applied, to discuss their effect on Ua and Li-ion concentration prediction. 2D reconstruction structures for the cathode is established with RCT,c effect considered. Finally, the Ua, Uc, and Ucell are successfully predicted at different C-rates. Results propose an accurate and versatile electrochemical model and highlight the importance of considering limiting factors in electrochemical modeling for fast charging.

AB - The acceleration of fast charging capabilities has emerged as a pivotal objective within the realms of the battery, electric vehicle, and energy storage sectors. However, the classical electrochemical models are not able to describe voltages of the cell (Ucell), anode (Ua), and cathode (Uc) at high C-rates. Herein, Ucell, Ua, and Uc are experimentally obtained under various C-rates (0.1–2C) and identified the charge transfer resistance of the cathode (RCT,c) as the primary rate-limiting factor. Thus, the anode is established as a multi-scale coupling model with Fick's law and phase separation model applied, to discuss their effect on Ua and Li-ion concentration prediction. 2D reconstruction structures for the cathode is established with RCT,c effect considered. Finally, the Ua, Uc, and Ucell are successfully predicted at different C-rates. Results propose an accurate and versatile electrochemical model and highlight the importance of considering limiting factors in electrochemical modeling for fast charging.

KW - charge transfer resistance

KW - electrochemical model

KW - fast charging

KW - lithium-ion battery

KW - phase separation

UR - https://www.scopus.com/pages/publications/85190548686

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DO - 10.1002/aenm.202400710

M3 - 文章

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SN - 1614-6832

VL - 14

JO - Advanced Energy Materials

JF - Advanced Energy Materials

IS - 26

M1 - 2400710

ER -

Electrochemical Modeling of Fast Charging in Batteries

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