CHAPTER 9: Understanding battery aging mechanisms

Li, D; Danilov, DL; Bergveld, HJ; Eichel, RA; Notten, PHL

CHAPTER 9: Understanding battery aging mechanisms

Li, D Danilov, DL Bergveld, HJ Eichel, RA Notten, PHL

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Publisher:: Royal Society of Chemistry
Publication Type:: Chapter
Citation:: RSC Catalysis Series, 2019, 2019-January, pp. 220-250
Issue Date:: 2019-01-01

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Field	Value	Language
dc.contributor.author	Li, D
dc.contributor.author	Danilov, DL
dc.contributor.author	Bergveld, HJ
dc.contributor.author	Eichel, RA
dc.contributor.author	Notten, PHL
dc.date.accessioned	2020-05-04T23:41:54Z
dc.date.available	2020-05-04T23:41:54Z
dc.date.issued	2019-01-01
dc.identifier.citation	RSC Catalysis Series, 2019, 2019-January, pp. 220-250
dc.identifier.isbn	9781788017237
dc.identifier.uri	http://hdl.handle.net/10453/140473
dc.description.abstract	© 2019 The Royal Society of Chemistry. The aging mechanisms of Li-ion batteries are introduced in this chapter, and are experimentally investigated and modeled. From SEM it is found that the thickness of the solid electrolyte interface layers at the graphite electrode surface increase upon aging. Deformation of the graphite structure is confirmed by Raman spectroscopy. XPS analyses show that transition metals dissolved from cathode are deposited onto the graphite electrode. Cathode dissolution at elevated temperatures is further confirmed by ICP measurements. Apart from postmortem analyses, a novel non-destructive approach is proposed to quantify the graphite electrode decay. A comprehensive electrochemistry model is proposed to simulate the irreversible capacity loss under various aging conditions. The dependence of the capacity loss on aging conditions, such as storage state of charge, cycling current, temperature, etc. is simulated and the simulations are in good agreement with the experiments. The degradation model allows researchers to have an in-depth understanding of aging mechanisms and therefore helps manufacturers to improve battery performance by optimizing manufacturing procedures. Moreover, the model can be further used to predict the battery cycle life, which can be used to develop more accurate battery management systems to increase battery efficiency and safety.
dc.language	en
dc.publisher	Royal Society of Chemistry
dc.relation.ispartof	RSC Catalysis Series
dc.relation.isbasedon	10.1039/9781788016124-00220
dc.rights	info:eu-repo/semantics/closedAccess
dc.title	CHAPTER 9: Understanding battery aging mechanisms
dc.type	Chapter
utslib.citation.volume	2019-January
pubs.organisational-group	/University of Technology Sydney/Faculty of Science
pubs.organisational-group	/University of Technology Sydney/Faculty of Science/School of Mathematical and Physical Sciences
pubs.organisational-group	/University of Technology Sydney
utslib.copyright.status	closed_access	*
dc.date.updated	2020-05-04T23:41:52Z
pubs.publication-status	Published
pubs.volume	2019-January
utslib.start-page	220

Abstract:

© 2019 The Royal Society of Chemistry. The aging mechanisms of Li-ion batteries are introduced in this chapter, and are experimentally investigated and modeled. From SEM it is found that the thickness of the solid electrolyte interface layers at the graphite electrode surface increase upon aging. Deformation of the graphite structure is confirmed by Raman spectroscopy. XPS analyses show that transition metals dissolved from cathode are deposited onto the graphite electrode. Cathode dissolution at elevated temperatures is further confirmed by ICP measurements. Apart from postmortem analyses, a novel non-destructive approach is proposed to quantify the graphite electrode decay. A comprehensive electrochemistry model is proposed to simulate the irreversible capacity loss under various aging conditions. The dependence of the capacity loss on aging conditions, such as storage state of charge, cycling current, temperature, etc. is simulated and the simulations are in good agreement with the experiments. The degradation model allows researchers to have an in-depth understanding of aging mechanisms and therefore helps manufacturers to improve battery performance by optimizing manufacturing procedures. Moreover, the model can be further used to predict the battery cycle life, which can be used to develop more accurate battery management systems to increase battery efficiency and safety.

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http://hdl.handle.net/10453/140473