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Abstract

Growth of lithium dendrites in solid state batteries is an important factor that disturbs their commercial applications. The growth of lithium dendrites at the interface of lithium metal anode will not only lead to the decrease of battery energy efficiency, but also cause combustion, explosion and other safety problems. In order to explore the factors and methods that inhibit the growth of lithium dendrites, the phase-field theory is used to simulate the growth of lithium dendrites in polymer solid electrolyte batteries, and a phase-field model of lithium dendrite growth coupled with mechanical stress and thermal field is established. The effects of key physical factors such as ambient temperature, solid electrolyte Young’s modulus and external stress on dendrite growth and their acting principles are discussed and analyzed. The results show that under the conditions of high temperature, high solid electrolyte Young’s modulus and external stress, the growth of lithium dendrites is slow, the number of long dendrites is small, and the electrodeposition is more uniform. In addition, the effects of Young’s modulus of solid electrolyte and ambient temperature on the growth of lithium dendrites in a common range are compared with each other. It is found that the inhibition effect of changing Young’s modulus of solid electrolyte on the maximum length of lithium dendrites is 19% higher than that caused by the change of ambient temperature.

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Corresponding author:Li Ding-Gen,lidinggen@hust.edu.cn

Funds:Project supported by the National Key R&D Program of China (Grant No. 2018YFB0104104).

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参数名称	值	文献
界面迁移率${L_\sigma}$/(10^–6m³·J^–1·s^–1)	2.5	[7]
动力学系数$ {L_\eta } $/s^–1	0.1	[15]
梯度能量系数$ {\kappa _0} $/(10^–5J·m^–1)	1.5	[16]
锂离子标准扩散系数$ {D_0}$/(10^–12m²·s^–1)	2.5	[17]
电极的电导率$ {\sigma _{\rm{s}}} $/(10⁷S·m^–1)	1.0	[8]
电解质的电导率$ {\sigma _{{\mathrm{l}}}} $/(10^–2S·m^–1)	3.5	[18]
电荷转移数$ \alpha $	0.5	[8]
对流换热系数h/(W·m^–2·K^–1)	10	[11]
热辐射系数$ {\varepsilon _{\text{R}}} $	0.49	[11]
电极比热容$ {C_{{\text{ps}}}} $/(J·g^–1·K^–1)	3.55	[19]
电解质比热容$ {C_{{\text{pl}}}} $/(J·g^–1·K^–1)	1.76	[18]
电极导热系数$ {\kappa ^{\mathrm{s}}} $/(W·m^–1·K^–1)	84.8	[20]
电解质导热系数$ {\kappa ^{\mathrm{l}}} $/(W·m^–1·K^–1)	0.45	[18]
电极杨氏模量$ {E^{\mathrm{s}}} $/GPa	4.9	[21]
聚合物电解质杨氏模量$ {E^{\mathrm{l}}} $/GPa	0.07	[18]
纳米填料杨氏模量$ {E^{\mathrm{f}}} $/GPa	300	[17]
泊松比$ \upsilon $	0.36	[10]

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Vol. 72, Issue 22 - 2023-11-20

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