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Gaussian-Process based inference of electrolyte decomposition reaction networks in Li-ion battery failure

Gaussian-Process based inference of electrolyte decomposition reaction networks in Li-ion battery failure
Gaussian-Process based inference of electrolyte decomposition reaction networks in Li-ion battery failure

Li-ion batteries (LIBs) are widely adopted in EVs and stationary battery energy storage due to their superior performance over other battery chemistries. But LIBs come with the risk of thermal runaway (TR) which can lead to fire and explosion of the LIB. Hence, improving our understanding of TR is key to improving LIB safety. To achieve this, we aim to develop a detailed model of LIB TR, as existing models are oversimplified and often lead to inaccuracies when compared to experiments. To build a realistic representation of the reaction network (RN) for LIB TR, we present a case study on the ethylene carbonate (EC) solvent component of the LIB electrolyte. We use a RN for EC identified from literature to build a micro-kinetic model and optimize it against experimental data. Parameters optimisation and sensitivity analysis for a complex RN is made possible by using Gaussian Processes (GPs). It is found that the only four of the 14 parameters influence the simulation output significantly. Also, this work highlights areas of GP development for improved surrogate modelling of this type of problem. From this the methodology can be scaled to larger networks and can be applied LIB TR models to improve their accuracy, which in turn will help the development of safer LIBs.

Gaussian Process, Li-ion battery, Reaction network analysis, Robust optimization, Thermal runaway
1570-7946
157-162
Elsevier BV
Bugryniec, Peter J.
81304c2a-d500-41b8-b165-d2edc3ff2e6f
Yeardley, Aaron
70b07a52-fffc-42b2-9ff0-3c870451a2df
Jain, Aarjav
41a3fdad-b4bd-43df-a3b0-ade37e968861
Price, Nicholas
68b298f8-511c-4ab5-b5d9-e38a13fa8d74
Vernuccio, Sergio
4bafd7f3-0943-4f6c-bc78-b4026516ccdb
Brown, Solomon F.
c8227f45-ea73-4094-ad1a-8bf14c608a5e
Bugryniec, Peter J.
81304c2a-d500-41b8-b165-d2edc3ff2e6f
Yeardley, Aaron
70b07a52-fffc-42b2-9ff0-3c870451a2df
Jain, Aarjav
41a3fdad-b4bd-43df-a3b0-ade37e968861
Price, Nicholas
68b298f8-511c-4ab5-b5d9-e38a13fa8d74
Vernuccio, Sergio
4bafd7f3-0943-4f6c-bc78-b4026516ccdb
Brown, Solomon F.
c8227f45-ea73-4094-ad1a-8bf14c608a5e

Bugryniec, Peter J., Yeardley, Aaron, Jain, Aarjav, Price, Nicholas, Vernuccio, Sergio and Brown, Solomon F. (2022) Gaussian-Process based inference of electrolyte decomposition reaction networks in Li-ion battery failure. In, Computer Aided Chemical Engineering. (Computer Aided Chemical Engineering, 51) Elsevier BV, pp. 157-162. (doi:10.1016/B978-0-323-95879-0.50027-8).

Record type: Book Section

Abstract

Li-ion batteries (LIBs) are widely adopted in EVs and stationary battery energy storage due to their superior performance over other battery chemistries. But LIBs come with the risk of thermal runaway (TR) which can lead to fire and explosion of the LIB. Hence, improving our understanding of TR is key to improving LIB safety. To achieve this, we aim to develop a detailed model of LIB TR, as existing models are oversimplified and often lead to inaccuracies when compared to experiments. To build a realistic representation of the reaction network (RN) for LIB TR, we present a case study on the ethylene carbonate (EC) solvent component of the LIB electrolyte. We use a RN for EC identified from literature to build a micro-kinetic model and optimize it against experimental data. Parameters optimisation and sensitivity analysis for a complex RN is made possible by using Gaussian Processes (GPs). It is found that the only four of the 14 parameters influence the simulation output significantly. Also, this work highlights areas of GP development for improved surrogate modelling of this type of problem. From this the methodology can be scaled to larger networks and can be applied LIB TR models to improve their accuracy, which in turn will help the development of safer LIBs.

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More information

Published date: 1 August 2022
Additional Information: Publisher Copyright: © 2022 Elsevier B.V.
Keywords: Gaussian Process, Li-ion battery, Reaction network analysis, Robust optimization, Thermal runaway

Identifiers

Local EPrints ID: 495594
URI: http://eprints.soton.ac.uk/id/eprint/495594
DOI: doi:10.1016/B978-0-323-95879-0.50027-8
ISSN: 1570-7946
PURE UUID: fe980c44-ff12-4d49-a074-90bc4b697c3a
ORCID for Sergio Vernuccio: ORCID iD orcid.org/0000-0003-1254-0293

Catalogue record

Date deposited: 19 Nov 2024 17:33
Last modified: 21 Nov 2024 03:11

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Contributors

Author: Peter J. Bugryniec
Author: Aaron Yeardley
Author: Aarjav Jain
Author: Nicholas Price
Author: Sergio Vernuccio ORCID iD
Author: Solomon F. Brown

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