Physicochemically-informed continuum level model of a solid electrolyte interphase growth in Li-ion batteries

Zelič, Klemen; Esmaeilpour, Meysam; Jana, Saibal; Mele, Igor; Wenzel, Wolfgang; Katrašnik, Tomaž

Physicochemically-informed continuum level model of a solid electrolyte interphase growth in Li-ion batteries
ID Zelič, Klemen (Avtor), ID Esmaeilpour, Meysam (Avtor), ID Jana, Saibal (Avtor), ID Mele, Igor (Avtor), ID Wenzel, Wolfgang (Avtor), ID Katrašnik, Tomaž (Avtor)

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Izvleček

Despite extensive research, understanding the SEI’s formation mechanism, structure, and its impact on battery performance remains challenging due to its complexity. To enable model-based design studies and to enhance understanding and prediction of the macroscopically observable consequences of SEI layer on battery performance and safety, continuum models featuring high level of prediction capability are needed. This objective of this paper is to resolve this challenge through an innovative physicochemically-informed continuum level model derived using a scale-bridging methodology, which, for the first time, enables highly consistent transfer of detailed KMC level based governing equations and reactions rates to the physicochemically-informed continuum level model. This was made possible by the innovative methodology relying on identification of rate-limiting reactions, deriving dynamic equations, and implementing dimensionality reduction. The resulting continuum model accurately replicates KMC results and experimental results while significantly reducing computational complexity. Furthermore, it, for the first time, enables distinguishing between ‘bad’, ‘good’, and ‘inorganic’ SEI growth scenarios on the continuum scale, offering valuable insights into electrode/electrolyte interface design. Due to its computational efficiency and scalability the proposed model can be integrated into higher-scale battery models, making possible advanced virtual performance, degradation and safety assessments with higher level of prediction capability.

Jezik:	Angleški jezik
Ključne besede:	Li-ion batteries, solid electrolyte interphase, molecular dynamics, kinetic Monte Carlo, continuum model, scale-bridging
Vrsta gradiva:	Članek v reviji
Tipologija:	1.01 - Izvirni znanstveni članek
Organizacija:	FS - Fakulteta za strojništvo
Status publikacije:	Objavljeno
Različica publikacije:	Objavljena publikacija
Leto izida:	2025
Št. strani:	11 str.
Številčenje:	Vol. 627, [art. no.] 235814
PID:	20.500.12556/RUL-164982
UDK:	621.3
ISSN pri članku:	0378-7753
DOI:	10.1016/j.jpowsour.2024.235814
COBISS.SI-ID:	215623427
Datum objave v RUL:	19.11.2024
Število ogledov:	41
Število prenosov:	273
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Gradivo je del revije

Naslov:	Journal of power sources
Skrajšan naslov:	J. power sources
Založnik:	Elsevier Sequoia
ISSN:	0378-7753
COBISS.SI-ID:	25782784

Licence

Licenca:	CC BY-NC-ND 4.0, Creative Commons Priznanje avtorstva-Nekomercialno-Brez predelav 4.0 Mednarodna

Povezava:	http://creativecommons.org/licenses/by-nc-nd/4.0/deed.sl
Opis:	Najbolj omejujoča licenca Creative Commons. Uporabniki lahko prenesejo in delijo delo v nekomercialne namene in ga ne smejo uporabiti za nobene druge namene.

Sekundarni jezik

Jezik:	Slovenski jezik
Ključne besede:	Litij ionske baterije, medfazni sloji, molekularna dinamika, kinetični Monte Karlo, kontinuumski model, prehod med skalam

Projekti

Financer:	Drugi - Drug financer ali več financerjev
Številka projekta:	957189 (BIG-MAP)

Financer:	Drugi - Drug financer ali več financerjev
Številka projekta:	101069910 (NEXTCELL)

Financer:	Drugi - Drug financer ali več financerjev
Številka projekta:	101103898 (NextBMS)

Financer:	ARRS - Agencija za raziskovalno dejavnost Republike Slovenije
Številka projekta:	P2-0401
Naslov:	Energetsko strojništvo

Financer:	ARRS - Agencija za raziskovalno dejavnost Republike Slovenije
Številka projekta:	J2-2494
Naslov:	Napredni večskalni model NMC katodnih materialov za izboljšane sisteme za shranjevanje energije naslednje generacije

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