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Percolating Interfacial Layers Enhance Conductivity in Polymer–Composite Electrolytes

Ji-young Ock, Amit Bhattacharya, Tao Wang, Catalin Gainaru, Yangyang Wang, Katie L. Browning, Michelle Lehmann, Md Anisur Rahman, Miaofang Chi, Fan Wang, Jong K. Keum, Logan T. Kearney, Tomonori Saito, Sheng Dai, Raphaële J. Clément, Alexei P. Sokolov, X. Chelsea Chen

2024Macromolecules20 citationsDOI

Abstract

This study investigates the impact of the ceramic particle size on the bulk and interfacial ion transport properties of composite polymer electrolytes. The ceramic particles used for this study are micrometer-sized commercial lithium lanthanum titanate (LLTO) powders and LLTO nanorods (NR) prepared in the laboratory. The polymer matrices are vinylene carbonate (VEC) based single-ion-conducting (SIC) and dual-ion-conducting (DIC) polymer electrolytes. Our results reveal that the addition of LLTO NR results in improved ion transport, while the addition of commercial LLTO is ineffective or even detrimental. We ascribe these results to the formation of an interfacial polymer layer around the LLTO particles with enhanced Li + mobility and estimate the thickness of the interfacial layer to be ∼5 nm. The high surface-to-volume ratio of the LLTO NR leads to the percolation of the interfacial region at a relatively low ceramic loading of 30 wt %. This study highlights the importance of achieving percolation of the interface region (as opposed to the particles themselves) within the composite electrolyte when the interfacial layer is the enhancement mechanism.

Topics & Concepts

Materials scienceElectrolytePercolation (cognitive psychology)CeramicComposite numberLithium (medication)PolymerConductivityChemical engineeringParticle (ecology)Ionic conductivityComposite materialChemistryPhysical chemistryElectrodeEndocrinologyNeuroscienceEngineeringGeologyMedicineOceanographyBiologyAdvanced Battery Materials and TechnologiesAdvancements in Battery MaterialsConducting polymers and applications
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