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Hauptverfasser: Schloms, Felix, Gullbrekken, Øystein, Kjelstrup, Signe
Format: Preprint
Veröffentlicht: 2024
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Online-Zugang:https://arxiv.org/abs/2411.14506
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author Schloms, Felix
Gullbrekken, Øystein
Kjelstrup, Signe
author_facet Schloms, Felix
Gullbrekken, Øystein
Kjelstrup, Signe
contents A nonequilibrium thermodynamic model is presented for the nonisothermal lithium-ion battery cell. Coupling coefficients, all significant for transport of heat, mass, charge and chemical reaction, were used to model profiles of temperature, concentration and electric potential for each layer of the cell. Electrode surfaces were modelled with excess properties. Extending earlier works, we included lithium diffusion in the electrodes, and explained the cell's thermal signature due to Peltier and Soret effects. We showed that the model is consistent with the second law of thermodynamics, meaning that the entropy production computed at steady state from entropy fluxes is equal to the integral over the sum of flux-force products. The procedure is beneficial in electrochemical cell modelling as it reveals inconsistencies. The model was solved for typical lithium-ion battery materials. The coupling coefficients for transport of salts and solvents lead to significant concentration polarization. Thermal polarization is then negligible. We show that a zero-valued heat flux is not necessarily synonymous with a zero temperature gradient. Results are important for efforts that aim to avoid local hot spots. A program code is made available for testing and applications. The program is designed to solve dynamic boundary value problems posed by the electrode surfaces.
format Preprint
id arxiv_https___arxiv_org_abs_2411_14506
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Lithium-ion battery modelling for nonisothermal conditions
Schloms, Felix
Gullbrekken, Øystein
Kjelstrup, Signe
Chemical Physics
A nonequilibrium thermodynamic model is presented for the nonisothermal lithium-ion battery cell. Coupling coefficients, all significant for transport of heat, mass, charge and chemical reaction, were used to model profiles of temperature, concentration and electric potential for each layer of the cell. Electrode surfaces were modelled with excess properties. Extending earlier works, we included lithium diffusion in the electrodes, and explained the cell's thermal signature due to Peltier and Soret effects. We showed that the model is consistent with the second law of thermodynamics, meaning that the entropy production computed at steady state from entropy fluxes is equal to the integral over the sum of flux-force products. The procedure is beneficial in electrochemical cell modelling as it reveals inconsistencies. The model was solved for typical lithium-ion battery materials. The coupling coefficients for transport of salts and solvents lead to significant concentration polarization. Thermal polarization is then negligible. We show that a zero-valued heat flux is not necessarily synonymous with a zero temperature gradient. Results are important for efforts that aim to avoid local hot spots. A program code is made available for testing and applications. The program is designed to solve dynamic boundary value problems posed by the electrode surfaces.
title Lithium-ion battery modelling for nonisothermal conditions
topic Chemical Physics
url https://arxiv.org/abs/2411.14506