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Tambio, S. J., Deschamps, M., Sarou-Kanian, V., Etiemble, A., Douillard, T., Maire, E. & Lestriez, B. (2017) Self-diffusion of electrolyte species in model battery electrodes using Magic Angle Spinning and Pulsed Field Gradient Nuclear Magnetic Resonance. Journal of Power Sources, 362 315–322.
Added by: Richard Baschera (2017-10-24 13:30:33) Last edited by: Richard Baschera (2017-10-27 13:11:31) |
| Type de référence: Article DOI: 10.1016/j.jpowsour.2017.07.010 Numéro d'identification (ISBN etc.): 0378-7753 Clé BibTeX: Tambio2017 Voir tous les détails bibliographiques  |
Catégories: ST2E Créateurs: Deschamps, Douillard, Etiemble, Lestriez, Maire, Sarou-Kanian, Tambio Collection: Journal of Power Sources |
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| Résumé |
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Lithium-ion batteries are electrochemical storage devices using the electrochemical activity of the lithium ion in relation to intercalation compounds owing to mass transport phenomena through diffusion. Diffusion of the lithium ion in the electrode pores has been poorly understood due to the lack of experimental techniques for measuring its self-diffusion coefficient in porous media. Magic-Angle Spinning, Pulsed Field Gradient, Stimulated-Echo Nuclear Magnetic Resonance (MAS-PFG-STE NMR) was used here for the first time to measure the self-diffusion coefficients of the electrolyte species in the LP30 battery electrolyte (i.e. a 1 M solution of LiPF6 dissolved in 1:1 Ethylene Carbonate - Dimethyl Carbonate) in model composites. These composite electrodes were made of alumina, carbon black and PVdF-HFP. Alumina's magnetic susceptibility is close to the measured magnetic susceptibility of the LP30 electrolyte thereby limiting undesirable internal field gradients. Interestingly, the self-diffusion coefficient of lithium ions decreases with increasing carbon content. FIB-SEM was used to describe the 3D geometry of the samples. The comparison between the reduction of self-diffusion coefficients as measured by PFG-NMR and as geometrically derived from FIB/SEM tortuosity values highlights the contribution of specific interactions at the material/electrolyte interface on the lithium transport properties. (C) 2017 Elsevier B.V. All rights reserved.
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