Fracture damage of nanowire lithium-ion battery electrode affected by diffusion-induced stress and bending during lithiation

Bingbing Chen; Jianqiu Zhou; Xuming Pang; Pengfei Wei; Yunbo Wu; Kunjun Deng

doi:10.1039/c4ra01724b

Fracture damage of nanowire lithium-ion battery electrode affected by diffusion-induced stress and bending during lithiation

Bingbing Chen, Jianqiu Zhou, Xuming Pang, Pengfei Wei, Yunbo Wu, Kunjun Deng

School of energy science and engineering

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

14 Scopus citations

Abstract

Lithium-ion battery electrode materials generally experience significant volume changes during lithium diffusion in charging and discharging. These volume changes lead to diffusion-induced stress and defect nucleation. By analyzing the stress, the bending associated with lithiation, we find that size reduction of the electrode can avoid the phenomenon of volume change. In this work, we build a relationship among the stress, bending, strain energy and size of the electrode. Also, the fracture energy of the electrode materials, which can be evaluated further by the strain energy, has been derived to optimize the electrode size for maximizing the battery life. Finally, a critical electrode size determination method is proposed. This journal is

Original language	English
Pages (from-to)	21072-21078
Number of pages	7
Journal	RSC Advances
Volume	4
Issue number	40
DOIs	https://doi.org/10.1039/c4ra01724b
State	Published - 2014

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abstract = "Lithium-ion battery electrode materials generally experience significant volume changes during lithium diffusion in charging and discharging. These volume changes lead to diffusion-induced stress and defect nucleation. By analyzing the stress, the bending associated with lithiation, we find that size reduction of the electrode can avoid the phenomenon of volume change. In this work, we build a relationship among the stress, bending, strain energy and size of the electrode. Also, the fracture energy of the electrode materials, which can be evaluated further by the strain energy, has been derived to optimize the electrode size for maximizing the battery life. Finally, a critical electrode size determination method is proposed. This journal is",

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T1 - Fracture damage of nanowire lithium-ion battery electrode affected by diffusion-induced stress and bending during lithiation

AU - Chen, Bingbing

AU - Zhou, Jianqiu

AU - Pang, Xuming

AU - Wei, Pengfei

AU - Wu, Yunbo

AU - Deng, Kunjun

PY - 2014

Y1 - 2014

N2 - Lithium-ion battery electrode materials generally experience significant volume changes during lithium diffusion in charging and discharging. These volume changes lead to diffusion-induced stress and defect nucleation. By analyzing the stress, the bending associated with lithiation, we find that size reduction of the electrode can avoid the phenomenon of volume change. In this work, we build a relationship among the stress, bending, strain energy and size of the electrode. Also, the fracture energy of the electrode materials, which can be evaluated further by the strain energy, has been derived to optimize the electrode size for maximizing the battery life. Finally, a critical electrode size determination method is proposed. This journal is

AB - Lithium-ion battery electrode materials generally experience significant volume changes during lithium diffusion in charging and discharging. These volume changes lead to diffusion-induced stress and defect nucleation. By analyzing the stress, the bending associated with lithiation, we find that size reduction of the electrode can avoid the phenomenon of volume change. In this work, we build a relationship among the stress, bending, strain energy and size of the electrode. Also, the fracture energy of the electrode materials, which can be evaluated further by the strain energy, has been derived to optimize the electrode size for maximizing the battery life. Finally, a critical electrode size determination method is proposed. This journal is

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JO - RSC Advances

JF - RSC Advances

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Fracture damage of nanowire lithium-ion battery electrode affected by diffusion-induced stress and bending during lithiation

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