Asymmetric Temperature Modulation for Extreme Fast Charging of Lithium-Ion Batteries

Xiao Guang Yang; Teng Liu; Yue Gao; Shanhai Ge; Yongjun Leng; Donghai Wang; Chao Yang Wang

doi:10.1016/j.joule.2019.09.021

Asymmetric Temperature Modulation for Extreme Fast Charging of Lithium-Ion Batteries

Xiao Guang Yang, Teng Liu, Yue Gao, Shanhai Ge, Yongjun Leng, Donghai Wang, Chao Yang Wang^*

^*此作品的通讯作者

科研成果: 期刊稿件 › 文章 › 同行评审

267 引用（Scopus）

摘要

Adding a 200-mile range in 10 min, so-called extreme fast charging (XFC), is the key to mainstream adoption of battery electric vehicles (BEVs). Here, we present an asymmetric temperature modulation (ATM) method that, on one hand, charges a Li-ion cell at an elevated temperature of 60°C to eliminate Li plating and, on the other, limits the exposure time at 60°C to only ∼10 min per cycle, or 0.1% of the lifetime of a BEV, to prevent severe solid-electrolyte-interphase growth. The asymmetric temperature between charge and discharge opens a new path to enhance kinetics and transport during charging while still achieving long life. We show that a 9.5-Ah 170-Wh/kg cell sustained 1,700 XFC cycles (6 C charge to 80% state of charge) at 20% capacity loss with the ATM, compared to 60 cycles for a control cell, and that a 209-Wh/kg BEV cell retained 91.7% capacity after 2,500 XFC cycles.

源语言	英语
页（从-至）	3002-3019
页数	18
期刊	Joule
卷	3
期	12
DOI	https://doi.org/10.1016/j.joule.2019.09.021
出版状态	已出版 - 18 12月 2019
已对外发布	是

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title = "Asymmetric Temperature Modulation for Extreme Fast Charging of Lithium-Ion Batteries",

abstract = "Adding a 200-mile range in 10 min, so-called extreme fast charging (XFC), is the key to mainstream adoption of battery electric vehicles (BEVs). Here, we present an asymmetric temperature modulation (ATM) method that, on one hand, charges a Li-ion cell at an elevated temperature of 60°C to eliminate Li plating and, on the other, limits the exposure time at 60°C to only ∼10 min per cycle, or 0.1% of the lifetime of a BEV, to prevent severe solid-electrolyte-interphase growth. The asymmetric temperature between charge and discharge opens a new path to enhance kinetics and transport during charging while still achieving long life. We show that a 9.5-Ah 170-Wh/kg cell sustained 1,700 XFC cycles (6 C charge to 80% state of charge) at 20% capacity loss with the ATM, compared to 60 cycles for a control cell, and that a 209-Wh/kg BEV cell retained 91.7% capacity after 2,500 XFC cycles.",

keywords = "battery degradation, extreme fast charging, high energy battery, high temperature, lithium plating, lithium-ion battery, solid-electrolyte interphase, thermal management",

author = "Yang, {Xiao Guang} and Teng Liu and Yue Gao and Shanhai Ge and Yongjun Leng and Donghai Wang and Wang, {Chao Yang}",

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T1 - Asymmetric Temperature Modulation for Extreme Fast Charging of Lithium-Ion Batteries

AU - Yang, Xiao Guang

AU - Liu, Teng

AU - Gao, Yue

AU - Ge, Shanhai

AU - Leng, Yongjun

AU - Wang, Donghai

AU - Wang, Chao Yang

PY - 2019/12/18

Y1 - 2019/12/18

N2 - Adding a 200-mile range in 10 min, so-called extreme fast charging (XFC), is the key to mainstream adoption of battery electric vehicles (BEVs). Here, we present an asymmetric temperature modulation (ATM) method that, on one hand, charges a Li-ion cell at an elevated temperature of 60°C to eliminate Li plating and, on the other, limits the exposure time at 60°C to only ∼10 min per cycle, or 0.1% of the lifetime of a BEV, to prevent severe solid-electrolyte-interphase growth. The asymmetric temperature between charge and discharge opens a new path to enhance kinetics and transport during charging while still achieving long life. We show that a 9.5-Ah 170-Wh/kg cell sustained 1,700 XFC cycles (6 C charge to 80% state of charge) at 20% capacity loss with the ATM, compared to 60 cycles for a control cell, and that a 209-Wh/kg BEV cell retained 91.7% capacity after 2,500 XFC cycles.

AB - Adding a 200-mile range in 10 min, so-called extreme fast charging (XFC), is the key to mainstream adoption of battery electric vehicles (BEVs). Here, we present an asymmetric temperature modulation (ATM) method that, on one hand, charges a Li-ion cell at an elevated temperature of 60°C to eliminate Li plating and, on the other, limits the exposure time at 60°C to only ∼10 min per cycle, or 0.1% of the lifetime of a BEV, to prevent severe solid-electrolyte-interphase growth. The asymmetric temperature between charge and discharge opens a new path to enhance kinetics and transport during charging while still achieving long life. We show that a 9.5-Ah 170-Wh/kg cell sustained 1,700 XFC cycles (6 C charge to 80% state of charge) at 20% capacity loss with the ATM, compared to 60 cycles for a control cell, and that a 209-Wh/kg BEV cell retained 91.7% capacity after 2,500 XFC cycles.

KW - battery degradation

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KW - high energy battery

KW - high temperature

KW - lithium plating

KW - lithium-ion battery

KW - solid-electrolyte interphase

KW - thermal management

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Asymmetric Temperature Modulation for Extreme Fast Charging of Lithium-Ion Batteries

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