A mathematical model for mechanically-induced deterioration of the binder in lithium-ion electrodes
A mathematical model for mechanically-induced deterioration of the binder in lithium-ion electrodes
This study is concerned with modeling detrimental deformations of the binder phase within lithium-ion batteries that occur during cell assembly and usage. A two-dimensional poro- viscoelastic model for the mechanical behavior of porous electrodes is formulated and posed on a geometry corresponding to a thin rectangular electrode, with a regular square array of microscopic circular electrode particles, stuck to a rigid base formed by the current collector. Deformation is forced both by (i) electrolyte absorption driven binder swelling, and; (ii) cyclic growth and shrinkage of electrode particles as the battery is charged and discharged. In order to deal with the complex- ity of the geometry the governing equations are upscaled to obtain macroscopic effective-medium equations. A solution to these equations is obtained, in the asymptotic limit that the height of the rectangular electrode is much smaller than its width, that shows the macroscopic deformation is one-dimensional, with growth confined to the vertical direction. The confinement of macroscopic deformations to one dimension is used to obtain boundary conditions on the microscopic problem for the deformations in a ’unit cell’ centered on a single electrode particle. The resulting microscale problem is solved using numerical (finite element) techniques. The two different forcing mechanisms are found to cause distinctly different patterns of deformation within the microstructure. Swelling of the binder induces stresses that tend to lead to binder delamination from the electrode particle surfaces in a direction parallel to the current collector, whilst cycling causes stresses that tend to lead to delamination orthogonal to that caused by swelling. The differences between the cycling-induced damage in both: (i) anodes and cathodes, and; (ii) fast and slow cycling are discussed. Finally, the model predictions are compared to microscopy images of nickel manganese cobalt oxide cathodes and a qualitative agreement is found.
2172-2198
Foster, J.M.
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Chapman, S.J.
2fb8f0b2-56ab-4ac7-8518-35abf1047cf9
Richardson, G.
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Protas, B.
6eaf58f4-b584-498a-af16-cd2c3f1f289e
Foster, J.M.
b93acb2c-f981-4d4b-bc01-b1bc8332facf
Chapman, S.J.
2fb8f0b2-56ab-4ac7-8518-35abf1047cf9
Richardson, G.
3fd8e08f-e615-42bb-a1ff-3346c5847b91
Protas, B.
6eaf58f4-b584-498a-af16-cd2c3f1f289e
Foster, J.M., Chapman, S.J., Richardson, G. and Protas, B.
(2017)
A mathematical model for mechanically-induced deterioration of the binder in lithium-ion electrodes.
SIAM Journal on Applied Mathematics, 77 (6), .
(doi:10.1137/16M1086595).
Abstract
This study is concerned with modeling detrimental deformations of the binder phase within lithium-ion batteries that occur during cell assembly and usage. A two-dimensional poro- viscoelastic model for the mechanical behavior of porous electrodes is formulated and posed on a geometry corresponding to a thin rectangular electrode, with a regular square array of microscopic circular electrode particles, stuck to a rigid base formed by the current collector. Deformation is forced both by (i) electrolyte absorption driven binder swelling, and; (ii) cyclic growth and shrinkage of electrode particles as the battery is charged and discharged. In order to deal with the complex- ity of the geometry the governing equations are upscaled to obtain macroscopic effective-medium equations. A solution to these equations is obtained, in the asymptotic limit that the height of the rectangular electrode is much smaller than its width, that shows the macroscopic deformation is one-dimensional, with growth confined to the vertical direction. The confinement of macroscopic deformations to one dimension is used to obtain boundary conditions on the microscopic problem for the deformations in a ’unit cell’ centered on a single electrode particle. The resulting microscale problem is solved using numerical (finite element) techniques. The two different forcing mechanisms are found to cause distinctly different patterns of deformation within the microstructure. Swelling of the binder induces stresses that tend to lead to binder delamination from the electrode particle surfaces in a direction parallel to the current collector, whilst cycling causes stresses that tend to lead to delamination orthogonal to that caused by swelling. The differences between the cycling-induced damage in both: (i) anodes and cathodes, and; (ii) fast and slow cycling are discussed. Finally, the model predictions are compared to microscopy images of nickel manganese cobalt oxide cathodes and a qualitative agreement is found.
Text
MECHANICS_SUB2_v2
- Accepted Manuscript
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Accepted/In Press date: 8 September 2017
e-pub ahead of print date: 7 December 2017
Identifiers
Local EPrints ID: 413922
URI: http://eprints.soton.ac.uk/id/eprint/413922
ISSN: 0036-1399
PURE UUID: 325f77b7-cc47-4fb0-84bd-65d6f409bf1b
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Date deposited: 11 Sep 2017 16:31
Last modified: 16 Mar 2024 05:43
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Author:
J.M. Foster
Author:
S.J. Chapman
Author:
B. Protas
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