"Knees" in lithium-ion battery aging trajectories

Peter M.  Attia; Alexander  Bills; Ferran Brosa  Planella; Philipp  Dechent; Goncalo Dos Reis; Matthieu  Dubarry; Paul  Gasper; Richard  Gilchrist; Samuel  Greenbank; David  Howey; Ouyang  Liu; Edwin  Khoo; Yuliya  Preger; Abhishek  Soni; Shashank  Sripad; Anna G.  Stefanopoulou; Valentin  Sulzer

doi:10.1149/1945-7111/ac6d13

"Knees" in lithium-ion battery aging trajectories

Peter M. Attia, Alexander Bills, Ferran Brosa Planella, Philipp Dechent, Goncalo Dos Reis, Matthieu Dubarry, Paul Gasper, Richard Gilchrist, Samuel Greenbank, David Howey, Ouyang Liu, Edwin Khoo, Yuliya Preger, Abhishek Soni, Shashank Sripad, Anna G. Stefanopoulou, Valentin Sulzer

School of Mathematics

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

Abstract

Lithium-ion batteries can last many years but sometimes exhibit rapid, nonlinear degradation that severely limits battery lifetime. In this work, we review prior work on "knees" in lithium-ion battery aging trajectories. We first review definitions for knees and three classes of "internal state trajectories" (termed snowball, hidden, and threshold trajectories) that can cause a knee. We then discuss six knee "pathways", including lithium plating, electrode saturation, resistance growth, electrolyte and additive depletion, percolation-limited connectivity, and mechanical deformation -- some of which have internal state trajectories with signals that are electrochemically undetectable. We also identify key design and usage sensitivities for knees. Finally, we discuss challenges and opportunities for knee modeling and prediction. Our findings illustrate the complexity and subtlety of lithium-ion battery degradation and can aid both academic and industrial efforts to improve battery lifetime.

Original language	English
Number of pages	93
Journal	Journal of the electrochemical society
Early online date	5 May 2022
DOIs	https://doi.org/10.1149/1945-7111/ac6d13
Publication status	E-pub ahead of print - 5 May 2022

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10.1149/1945-7111/ac6d13Licence: Creative Commons: Attribution (CC-BY)

2201.02891Accepted author manuscript, 16.8 MB

https://arxiv.org/abs/2201.02891

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Attia, Peter M. ; Bills, Alexander ; Planella, Ferran Brosa ; Dechent, Philipp ; Dos Reis, Goncalo ; Dubarry, Matthieu ; Gasper, Paul ; Gilchrist, Richard ; Greenbank, Samuel ; Howey, David ; Liu, Ouyang ; Khoo, Edwin ; Preger, Yuliya ; Soni, Abhishek ; Sripad, Shashank ; Stefanopoulou, Anna G. ; Sulzer, Valentin . / "Knees" in lithium-ion battery aging trajectories. In: Journal of the electrochemical society. 2022.

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title = "{"}Knees{"} in lithium-ion battery aging trajectories",

abstract = "Lithium-ion batteries can last many years but sometimes exhibit rapid, nonlinear degradation that severely limits battery lifetime. In this work, we review prior work on {"}knees{"} in lithium-ion battery aging trajectories. We first review definitions for knees and three classes of {"}internal state trajectories{"} (termed snowball, hidden, and threshold trajectories) that can cause a knee. We then discuss six knee {"}pathways{"}, including lithium plating, electrode saturation, resistance growth, electrolyte and additive depletion, percolation-limited connectivity, and mechanical deformation -- some of which have internal state trajectories with signals that are electrochemically undetectable. We also identify key design and usage sensitivities for knees. Finally, we discuss challenges and opportunities for knee modeling and prediction. Our findings illustrate the complexity and subtlety of lithium-ion battery degradation and can aid both academic and industrial efforts to improve battery lifetime. ",

author = "Attia, {Peter M.} and Alexander Bills and Planella, {Ferran Brosa} and Philipp Dechent and {Dos Reis}, Goncalo and Matthieu Dubarry and Paul Gasper and Richard Gilchrist and Samuel Greenbank and David Howey and Ouyang Liu and Edwin Khoo and Yuliya Preger and Abhishek Soni and Shashank Sripad and Stefanopoulou, {Anna G.} and Valentin Sulzer",

year = "2022",

month = may,

day = "5",

doi = "10.1149/1945-7111/ac6d13",

language = "English",

journal = "Journal of the electrochemical society",

issn = "0013-4651",

publisher = "Electrochemical Society, Inc.",

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"Knees" in lithium-ion battery aging trajectories. / Attia, Peter M. ; Bills, Alexander ; Planella, Ferran Brosa ; Dechent, Philipp ; Dos Reis, Goncalo; Dubarry, Matthieu ; Gasper, Paul ; Gilchrist, Richard ; Greenbank, Samuel ; Howey, David ; Liu, Ouyang ; Khoo, Edwin ; Preger, Yuliya ; Soni, Abhishek ; Sripad, Shashank ; Stefanopoulou, Anna G. ; Sulzer, Valentin .

In: Journal of the electrochemical society, 05.05.2022.

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

TY - JOUR

T1 - "Knees" in lithium-ion battery aging trajectories

AU - Attia, Peter M.

AU - Bills, Alexander

AU - Planella, Ferran Brosa

AU - Dechent, Philipp

AU - Dos Reis, Goncalo

AU - Dubarry, Matthieu

AU - Gasper, Paul

AU - Gilchrist, Richard

AU - Greenbank, Samuel

AU - Howey, David

AU - Liu, Ouyang

AU - Khoo, Edwin

AU - Preger, Yuliya

AU - Soni, Abhishek

AU - Sripad, Shashank

AU - Stefanopoulou, Anna G.

AU - Sulzer, Valentin

PY - 2022/5/5

Y1 - 2022/5/5

N2 - Lithium-ion batteries can last many years but sometimes exhibit rapid, nonlinear degradation that severely limits battery lifetime. In this work, we review prior work on "knees" in lithium-ion battery aging trajectories. We first review definitions for knees and three classes of "internal state trajectories" (termed snowball, hidden, and threshold trajectories) that can cause a knee. We then discuss six knee "pathways", including lithium plating, electrode saturation, resistance growth, electrolyte and additive depletion, percolation-limited connectivity, and mechanical deformation -- some of which have internal state trajectories with signals that are electrochemically undetectable. We also identify key design and usage sensitivities for knees. Finally, we discuss challenges and opportunities for knee modeling and prediction. Our findings illustrate the complexity and subtlety of lithium-ion battery degradation and can aid both academic and industrial efforts to improve battery lifetime.

AB - Lithium-ion batteries can last many years but sometimes exhibit rapid, nonlinear degradation that severely limits battery lifetime. In this work, we review prior work on "knees" in lithium-ion battery aging trajectories. We first review definitions for knees and three classes of "internal state trajectories" (termed snowball, hidden, and threshold trajectories) that can cause a knee. We then discuss six knee "pathways", including lithium plating, electrode saturation, resistance growth, electrolyte and additive depletion, percolation-limited connectivity, and mechanical deformation -- some of which have internal state trajectories with signals that are electrochemically undetectable. We also identify key design and usage sensitivities for knees. Finally, we discuss challenges and opportunities for knee modeling and prediction. Our findings illustrate the complexity and subtlety of lithium-ion battery degradation and can aid both academic and industrial efforts to improve battery lifetime.

U2 - 10.1149/1945-7111/ac6d13

DO - 10.1149/1945-7111/ac6d13

M3 - Review article

JO - Journal of the electrochemical society

JF - Journal of the electrochemical society

SN - 0013-4651

ER -

"Knees" in lithium-ion battery aging trajectories

Abstract

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