Electrochemical-mechanical coupled modeling and parameterization of swelling and ionic transport in lithium-ion batteries

The intercalation and aging induced volume changes of lithium-ion battery electrodes lead to significant mechanical pressure or volume changes on cell and module level. As the correlation between electrochemical and mechanical performance of lithium ion batteries at nano and macro scale requires a c...

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Bibliographic Details
Published in:Journal of power sources 2018-02, Vol.378, p.235-247
Main Authors: Sauerteig, Daniel, Hanselmann, Nina, Arzberger, Arno, Reinshagen, Holger, Ivanov, Svetlozar, Bund, Andreas
Format: Article
Language:English
Subjects:
Compression
Expansion
Lithium ion battery
Mechanical
Simulation
Stress
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Summary:The intercalation and aging induced volume changes of lithium-ion battery electrodes lead to significant mechanical pressure or volume changes on cell and module level. As the correlation between electrochemical and mechanical performance of lithium ion batteries at nano and macro scale requires a comprehensive and multidisciplinary approach, physical modeling accounting for chemical and mechanical phenomena during operation is very useful for the battery design. Since the introduced fully-coupled physical model requires proper parameterization, this work also focuses on identifying appropriate mathematical representation of compressibility as well as the ionic transport in the porous electrodes and the separator. The ionic transport is characterized by electrochemical impedance spectroscopy (EIS) using symmetric pouch cells comprising LiNi1/3Mn1/3Co1/3O2 (NMC) cathode, graphite anode and polyethylene separator. The EIS measurements are carried out at various mechanical loads. The observed decrease of the ionic conductivity reveals a significant transport limitation at high pressures. The experimentally obtained data are applied as input to the electrochemical-mechanical model of a prismatic 10 Ah cell. Our computational approach accounts intercalation induced electrode expansion, stress generation caused by mechanical boundaries, compression of the electrodes and the separator, outer expansion of the cell and finally the influence of the ionic transport within the electrolyte. •Implementation of a fully-coupled electrochemical-mechanical model.•Swelling induced macroscopic mechanical stress due to external compression.•Parameterization and implementation of pressure-dependent ionic transport.•Electrical and mechanical validation using a 10 Ah hard case cell.•Enhanced heterogeneous lithiation of the anode at elevated stress levels.
ISSN:0378-7753
1873-2755
DOI:10.1016/j.jpowsour.2017.12.044