Graded lithium-ion battery pouch cells to homogenise current distributions and mitigate lithium plating
Graded lithium-ion battery pouch cells to homogenise current distributions and mitigate lithium plating
Spatial distributions in current, temperature, state-of-charge and degradation across the plane of large format lithium-ion battery pouch cells can significantly impact their performance, especially at high C-rates. In this paper, a method to smooth out these spatial distributions by grading the electrode microstructure in-the-plane is proposed. A mathematical model of a large format pouch cell is developed and validated against both temperature and voltage experimental data. An analytic solution for the optimal graded electrode that achieves a uniform current distribution across the pouch cell is then derived. The model predicts that the graded electrodes could significantly reduce the likelihood of lithium plating in large format pouch cells, with grading increasing the C-rate at which plating occurs from 2.75C to 5.5C. These results indicate the potential of designing spatially varying electrode architectures to homogenise the response of large format pouch cells and improve their high rate performance.
cond-mat.mtrl-sci, physics.app-ph
Drummond, R.
45b997fe-e5e3-4d81-95ce-401f98d5dd8b
Tredenick, E.C.
a3341146-0b29-4f0e-bdac-b0b2bdd59f72
Kirk, T.L.
7bad334e-c216-4f4a-b6b3-cca90324b37c
Forghani, M.
d0802a2b-8aa1-4e3c-b715-d188ce0bb9d5
Grant, P.S.
8b1894eb-8cc1-48c7-b1bd-5593cbc67467
Duncan, S.R.
51bbf209-1f4e-4fd1-b4e0-a803b0e43063
Drummond, R.
45b997fe-e5e3-4d81-95ce-401f98d5dd8b
Tredenick, E.C.
a3341146-0b29-4f0e-bdac-b0b2bdd59f72
Kirk, T.L.
7bad334e-c216-4f4a-b6b3-cca90324b37c
Forghani, M.
d0802a2b-8aa1-4e3c-b715-d188ce0bb9d5
Grant, P.S.
8b1894eb-8cc1-48c7-b1bd-5593cbc67467
Duncan, S.R.
51bbf209-1f4e-4fd1-b4e0-a803b0e43063
[Unknown type: UNSPECIFIED]
Abstract
Spatial distributions in current, temperature, state-of-charge and degradation across the plane of large format lithium-ion battery pouch cells can significantly impact their performance, especially at high C-rates. In this paper, a method to smooth out these spatial distributions by grading the electrode microstructure in-the-plane is proposed. A mathematical model of a large format pouch cell is developed and validated against both temperature and voltage experimental data. An analytic solution for the optimal graded electrode that achieves a uniform current distribution across the pouch cell is then derived. The model predicts that the graded electrodes could significantly reduce the likelihood of lithium plating in large format pouch cells, with grading increasing the C-rate at which plating occurs from 2.75C to 5.5C. These results indicate the potential of designing spatially varying electrode architectures to homogenise the response of large format pouch cells and improve their high rate performance.
Text
2407.21071v1
- Author's Original
More information
Accepted/In Press date: 18 December 2024
Keywords:
cond-mat.mtrl-sci, physics.app-ph
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Local EPrints ID: 496665
URI: http://eprints.soton.ac.uk/id/eprint/496665
PURE UUID: 49eb7de7-90d8-4b27-8021-08d4d5400e6e
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Date deposited: 07 Jan 2025 19:05
Last modified: 10 Jan 2025 03:21
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Contributors
Author:
R. Drummond
Author:
E.C. Tredenick
Author:
T.L. Kirk
Author:
M. Forghani
Author:
P.S. Grant
Author:
S.R. Duncan
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