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Effect of Flame Retardants and Electrolyte Variations on Li-Ion Batteries

Natalia Fulik, Andreas Hofmann, Dorit Nötzel, Marcus Müller, I. Reuter, Freya Müller, Anna Smith, Thomas Hanemann

2023Batteries11 citationsDOIOpen Access PDF

Abstract

Lithium-ion batteries are being increasingly used and deployed commercially. Cell-level improvements that address flammability characteristics and thermal runaway are currently being intensively tested and explored. In this study, three additives—namely, lithium oxalate, sodium fumarate and sodium malonate—which exhibit fire-retardant properties are investigated with respect to their incorporation into graphite anodes and their electro/chemical interactions within the anode and the cell material studied. It has been shown that flame-retardant concentrations of up to approximately 20 wt.% within the anode coating do not cause significant capacity degradation but can provide a flame-retardant effect due to their inherent, fire-retardant release of CO2 gas. The flame-retardant-containing layers exhibit good adhesion to the current collector. Their suitability in lithium-ion cells was tested in pouch cells and, when compared to pure graphite anodes, showed almost no deterioration regarding cell capacity when used in moderate (≤20 wt.%) concentrations.

Topics & Concepts

Fire retardantAnodeElectrolyteMaterials scienceFlammabilityLithium (medication)Thermal runawayChemical engineeringCoatingCone calorimeterSodiumDegradation (telecommunications)GraphiteStringerComposite materialPyrolysisChemistryBattery (electricity)MetallurgyMedicineComputer sciencePhysicsEndocrinologyPower (physics)ElectrodeEngineeringQuantum mechanicsCharPhysical chemistryTelecommunicationsAdvanced Battery Technologies ResearchAdvancements in Battery MaterialsAdvanced Battery Materials and Technologies
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