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A coupled phase field formulation for modelling fatigue cracking in lithium-ion battery electrode particles

Тип публикацииJournal Article
Дата публикации2022-10-01
SCImago Q1
Tоп 10% SCImago
WOS Q1
БС1
SJR1.598
CiteScore12.2
Impact factor8.4
ISSN03787753, 18732755
Physical and Theoretical Chemistry
Electrical and Electronic Engineering
Energy Engineering and Power Technology
Renewable Energy, Sustainability and the Environment
Краткое описание
Electrode particle cracking is one of the main phenomena driving battery capacity degradation. Recent phase field fracture studies have investigated particle cracking behaviour. However, only the beginning of life has been considered and effects such as damage accumulation have been neglected. Here, a multi-physics phase field fatigue model has been developed to study crack propagation in battery electrode particles undergoing hundreds of cycles. In addition, we couple our electrochemo-mechanical formulation with X-ray CT imaging to simulate fatigue cracking of realistic particle microstructures. Using this modelling framework, non-linear crack propagation behaviour is predicted, leading to the observation of an exponential increase in cracked area with cycle number. Three stages of crack growth (slow, accelerating and unstable) are observed, with phenomena such as crack initialisation at concave regions and crack coalescence having a significant contribution to the resulting fatigue crack growth rates. The critical values of C-rate, particle size and initial crack length are determined, and found to be lower than those reported in the literature using static fracture models. Therefore, this work demonstrates the importance of considering fatigue damage in battery degradation models and provides insights on the control of fatigue crack propagation to alleviate battery capacity degradation. • We present the first phase field model for fatigue damage in battery electrodes. • Fatigue damage over hundreds of cycles is predicted for several particle geometries. • Critical values of C-rate, particle size and initial crack length are estimated. • Critical threshold values are much lower than those reported using static fracture. • Realistic microstructures are investigated by coupling the model with X-CT imaging.
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Engineering Fracture Mechanics
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ГОСТ |
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Ai W. et al. A coupled phase field formulation for modelling fatigue cracking in lithium-ion battery electrode particles // Journal of Power Sources. 2022. Vol. 544. p. 231805.
ГОСТ со всеми авторами (до 50) Скопировать
Ai W., Wu B., Martinez-Paneda E. A coupled phase field formulation for modelling fatigue cracking in lithium-ion battery electrode particles // Journal of Power Sources. 2022. Vol. 544. p. 231805.
RIS |
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TY - JOUR
DO - 10.1016/j.jpowsour.2022.231805
UR - https://doi.org/10.1016/j.jpowsour.2022.231805
TI - A coupled phase field formulation for modelling fatigue cracking in lithium-ion battery electrode particles
T2 - Journal of Power Sources
AU - Ai, Weilong
AU - Wu, Billy
AU - Martinez-Paneda, Emilio
PY - 2022
DA - 2022/10/01
PB - Elsevier
SP - 231805
VL - 544
SN - 0378-7753
SN - 1873-2755
ER -
BibTex
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BibTex (до 50 авторов) Скопировать
@article{2022_Ai,
author = {Weilong Ai and Billy Wu and Emilio Martinez-Paneda},
title = {A coupled phase field formulation for modelling fatigue cracking in lithium-ion battery electrode particles},
journal = {Journal of Power Sources},
year = {2022},
volume = {544},
publisher = {Elsevier},
month = {oct},
url = {https://doi.org/10.1016/j.jpowsour.2022.231805},
pages = {231805},
doi = {10.1016/j.jpowsour.2022.231805}
}
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