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Towards a micro-kinetic model of Li-ion battery thermal runaway — reaction network analysis of dimethyl carbonate thermal decomposition

Towards a micro-kinetic model of Li-ion battery thermal runaway — reaction network analysis of dimethyl carbonate thermal decomposition
Towards a micro-kinetic model of Li-ion battery thermal runaway — reaction network analysis of dimethyl carbonate thermal decomposition

Thermal runaway (TR), a major safety concern for Li-ion batteries (LIBs), involves a complex network of chemical reactions leading to the production of flammable and toxic gases. Computational modelling of LIB TR continues to aid safer battery design. But to improve the capability of TR simulations, here we apply micro-kinetic modelling to describe the kinetics of LIB TR at a mechanistic level. We focused on developing a micro-kinetic model for the thermal decomposition of dimethyl carbonate, an important electrolyte component. Comparing two reaction networks for this process, (1) not involving radical pathways and (2) involving radical pathways, we show that radical reaction pathways are important for the decomposition of DMC at low temperatures in the region of TR onset. Further, this second network is important for the accurate prediction of off-gas species. This work forms the basis of being able to predict hazardous species production. With further work to develop a reaction network for the decomposition of the entire electrolyte and electrode-electrolyte reactions, predictive capabilities can be extended to allow for detailed risk assessment of LIBs.

Degradation, Density functional theory, Electrolyte, Fire safety, Gas composition
0378-7753
Bugryniec, Peter J.
81304c2a-d500-41b8-b165-d2edc3ff2e6f
Vernuccio, Sergio
4bafd7f3-0943-4f6c-bc78-b4026516ccdb
Brown, Solomon F.
c8227f45-ea73-4094-ad1a-8bf14c608a5e
Bugryniec, Peter J.
81304c2a-d500-41b8-b165-d2edc3ff2e6f
Vernuccio, Sergio
4bafd7f3-0943-4f6c-bc78-b4026516ccdb
Brown, Solomon F.
c8227f45-ea73-4094-ad1a-8bf14c608a5e

Bugryniec, Peter J., Vernuccio, Sergio and Brown, Solomon F. (2023) Towards a micro-kinetic model of Li-ion battery thermal runaway — reaction network analysis of dimethyl carbonate thermal decomposition. Journal of Power Sources, 580, [233394]. (doi:10.1016/j.jpowsour.2023.233394).

Record type: Article

Abstract

Thermal runaway (TR), a major safety concern for Li-ion batteries (LIBs), involves a complex network of chemical reactions leading to the production of flammable and toxic gases. Computational modelling of LIB TR continues to aid safer battery design. But to improve the capability of TR simulations, here we apply micro-kinetic modelling to describe the kinetics of LIB TR at a mechanistic level. We focused on developing a micro-kinetic model for the thermal decomposition of dimethyl carbonate, an important electrolyte component. Comparing two reaction networks for this process, (1) not involving radical pathways and (2) involving radical pathways, we show that radical reaction pathways are important for the decomposition of DMC at low temperatures in the region of TR onset. Further, this second network is important for the accurate prediction of off-gas species. This work forms the basis of being able to predict hazardous species production. With further work to develop a reaction network for the decomposition of the entire electrolyte and electrode-electrolyte reactions, predictive capabilities can be extended to allow for detailed risk assessment of LIBs.

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Accepted/In Press date: 5 July 2023
e-pub ahead of print date: 26 July 2023
Published date: 1 October 2023
Additional Information: Publisher Copyright: © 2023 The Author(s)
Keywords: Degradation, Density functional theory, Electrolyte, Fire safety, Gas composition

Identifiers

Local EPrints ID: 495753
URI: http://eprints.soton.ac.uk/id/eprint/495753
DOI: doi:10.1016/j.jpowsour.2023.233394
ISSN: 0378-7753
PURE UUID: 62b42d90-e4b1-4027-b910-1d3f6f594d6d
ORCID for Sergio Vernuccio: ORCID iD orcid.org/0000-0003-1254-0293

Catalogue record

Date deposited: 21 Nov 2024 17:49
Last modified: 23 Nov 2024 03:13

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Contributors

Author: Peter J. Bugryniec
Author: Sergio Vernuccio ORCID iD
Author: Solomon F. Brown

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