Köbbing, Lukas und Kuhn, Yannick und Horstmann, Birger (2024) Slow Voltage Relaxation of Silicon Nanoparticles with a Chemo-Mechanical Core-Shell Model. ACS Applied Materials and Interfaces, 16 (49), Seiten 67609-67619. American Chemical society (ACS). doi: 10.1021/acsami.4c12976. ISSN 1944-8244.
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Offizielle URL: https://pubs.acs.org/doi/10.1021/acsami.4c12976
Kurzfassung
Silicon presents itself as a high-capacity anode material for lithium-ion batteries with a promising future. The high ability for lithiation comes along with massive volume changes and a problematic voltage hysteresis, causing reduced efficiency, detrimental heat generation, and a complicated state-of-charge estimation. During slow cycling, amorphous silicon nanoparticles show a larger voltage hysteresis than after relaxation periods. Interestingly, the voltage relaxes for at least several days, which has not been physically explained so far. We apply a chemo-mechanical continuum model in a core-shell geometry interpreted as a silicon particle covered by the solid-electrolyte interphase to account for the hysteresis phenomena. The silicon core (de)lithiates during every cycle while the covering shell is chemically inactive. The visco-elastoplastic behavior of the shell explains the voltage hysteresis during cycling and after relaxation. We identify a logarithmic voltage relaxation, which fits with the established Garofalo law for viscosity. Our chemo-mechanical model describes the observed voltage hysteresis phenomena and outperforms the empirical Plett model. In addition to our full model, we present a reduced model to allow for easy voltage profile estimations. The presented results support the mechanical explanation of the silicon voltage hysteresis with a core-shell model and encourage further efforts into the investigation of the silicon anode mechanics.
elib-URL des Eintrags: | https://elib.dlr.de/207757/ | ||||||||||||||||
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Dokumentart: | Zeitschriftenbeitrag | ||||||||||||||||
Titel: | Slow Voltage Relaxation of Silicon Nanoparticles with a Chemo-Mechanical Core-Shell Model | ||||||||||||||||
Autoren: |
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Datum: | 26 November 2024 | ||||||||||||||||
Erschienen in: | ACS Applied Materials and Interfaces | ||||||||||||||||
Referierte Publikation: | Ja | ||||||||||||||||
Open Access: | Ja | ||||||||||||||||
Gold Open Access: | Nein | ||||||||||||||||
In SCOPUS: | Ja | ||||||||||||||||
In ISI Web of Science: | Ja | ||||||||||||||||
Band: | 16 | ||||||||||||||||
DOI: | 10.1021/acsami.4c12976 | ||||||||||||||||
Seitenbereich: | Seiten 67609-67619 | ||||||||||||||||
Verlag: | American Chemical society (ACS) | ||||||||||||||||
ISSN: | 1944-8244 | ||||||||||||||||
Status: | veröffentlicht | ||||||||||||||||
Stichwörter: | Silicon Voltage Relaxation, Silicon Anode, Silicon-SEI Mechanics, Visco-elastoplastic Model, Lithium-Ion Batteries | ||||||||||||||||
HGF - Forschungsbereich: | Energie | ||||||||||||||||
HGF - Programm: | Materialien und Technologien für die Energiewende | ||||||||||||||||
HGF - Programmthema: | Elektrochemische Energiespeicherung | ||||||||||||||||
DLR - Schwerpunkt: | Energie | ||||||||||||||||
DLR - Forschungsgebiet: | E SP - Energiespeicher | ||||||||||||||||
DLR - Teilgebiet (Projekt, Vorhaben): | E - Elektrochemische Speicher, E - Elektrochemische Prozesse | ||||||||||||||||
Standort: | Ulm | ||||||||||||||||
Institute & Einrichtungen: | Institut für Technische Thermodynamik > Computergestützte Elektrochemie | ||||||||||||||||
Hinterlegt von: | Köbbing, Lukas | ||||||||||||||||
Hinterlegt am: | 31 Okt 2024 14:22 | ||||||||||||||||
Letzte Änderung: | 17 Dez 2024 17:59 |
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