The redox aspects of lithium-ion batteries

Pekka Peljo; Claire Villevieille; Hubert H. Girault

doi:10.1039/d4ee04560b

The redox aspects of lithium-ion batteries

Pekka Peljo^*, Claire Villevieille, Hubert H. Girault^*

^*Corresponding author for this work

Department of Chemistry and Materials Science

Research output: Contribution to journal › Review Article › peer-review

Abstract

This article aims to present the redox aspects of lithium-ion batteries both from a thermodynamic and from a conductivity viewpoint. We first recall the basic definitions of the electrochemical potential of the electron, and of the Fermi level for a redox couple in solutions. The Fermi level of redox solids such as metal oxide particles is then discussed, and a Nernst equation is derived for two ideal systems, namely an ideally homogenous phase where the oxidised and reduced metal ions are homogeneously distributed and two segregated phases where the oxidised and the reduced metal ions are separated in two distinct phases such as observed, for example, in biphasic lithium iron phosphate. The two different Nernst equations are then used to explain the difference in conductivity, the former being more conductive due to redox conductivity.

Original language	English
Journal	Energy and Environmental Science
DOIs	https://doi.org/10.1039/d4ee04560b
Publication status	E-pub ahead of print - 14 Dec 2024
MoE publication type	A2 Review article, Literature review, Systematic review

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10.1039/d4ee04560bLicence: CC BY

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title = "The redox aspects of lithium-ion batteries",

abstract = "This article aims to present the redox aspects of lithium-ion batteries both from a thermodynamic and from a conductivity viewpoint. We first recall the basic definitions of the electrochemical potential of the electron, and of the Fermi level for a redox couple in solutions. The Fermi level of redox solids such as metal oxide particles is then discussed, and a Nernst equation is derived for two ideal systems, namely an ideally homogenous phase where the oxidised and reduced metal ions are homogeneously distributed and two segregated phases where the oxidised and the reduced metal ions are separated in two distinct phases such as observed, for example, in biphasic lithium iron phosphate. The two different Nernst equations are then used to explain the difference in conductivity, the former being more conductive due to redox conductivity.",

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AU - Peljo, Pekka

AU - Villevieille, Claire

AU - Girault, Hubert H.

PY - 2024/12/14

Y1 - 2024/12/14

N2 - This article aims to present the redox aspects of lithium-ion batteries both from a thermodynamic and from a conductivity viewpoint. We first recall the basic definitions of the electrochemical potential of the electron, and of the Fermi level for a redox couple in solutions. The Fermi level of redox solids such as metal oxide particles is then discussed, and a Nernst equation is derived for two ideal systems, namely an ideally homogenous phase where the oxidised and reduced metal ions are homogeneously distributed and two segregated phases where the oxidised and the reduced metal ions are separated in two distinct phases such as observed, for example, in biphasic lithium iron phosphate. The two different Nernst equations are then used to explain the difference in conductivity, the former being more conductive due to redox conductivity.

AB - This article aims to present the redox aspects of lithium-ion batteries both from a thermodynamic and from a conductivity viewpoint. We first recall the basic definitions of the electrochemical potential of the electron, and of the Fermi level for a redox couple in solutions. The Fermi level of redox solids such as metal oxide particles is then discussed, and a Nernst equation is derived for two ideal systems, namely an ideally homogenous phase where the oxidised and reduced metal ions are homogeneously distributed and two segregated phases where the oxidised and the reduced metal ions are separated in two distinct phases such as observed, for example, in biphasic lithium iron phosphate. The two different Nernst equations are then used to explain the difference in conductivity, the former being more conductive due to redox conductivity.

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AN - SCOPUS:85216070690

SN - 1754-5692

JO - Energy and Environmental Science

JF - Energy and Environmental Science

ER -

The redox aspects of lithium-ion batteries

Abstract

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