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Modeling the Electrical Conductive Paths within All‐Solid‐State Battery Electrodes

Clara Sangrós Giménez, Laura Helmers, Carsten Schilde, Alexander C. Diener, Arno Kwade

2020Chemical Engineering & Technology46 citationsDOIOpen Access PDF

Abstract

Abstract All‐solid‐state batteries constitute a very promising energy storage device. Two very important properties of these battery cells are the ionic and the electrical conductivity, which describe the ion and the electron transport through the electrodes, respectively. In this work, a numerical method is presented to model the electrical conductivity, considering the outcome of discrete‐element method simulations and the intrinsic conductivities of both the active material particles and the conductive additive particles. The results are calibrated and validated with the help of experimental data of real manufactured electrodes. The tortuosity, which strongly influences the ionic conductivity, is also presented for the analyzed electrodes, taking their microstructure into account.

Topics & Concepts

TortuosityElectrodeElectrical conductorMaterials scienceBattery (electricity)Electrical resistivity and conductivityConductivityIonic conductivityIonic bondingMicrostructureWork (physics)Composite materialIonChemical engineeringElectrical engineeringChemistryMechanical engineeringThermodynamicsPower (physics)EngineeringElectrolytePhysicsPorosityOrganic chemistryPhysical chemistryAdvanced Battery Materials and TechnologiesAdvanced Battery Technologies ResearchAdvancements in Battery Materials