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Discrete element modelling of the elastic-plastic and viscoelastic properties of a lithium-ion battery electrode layer

Axel Lundkvist, Per‐Lennart Larsson, Anand H.S. Iyer, Erik Olsson

2024Powder Technology21 citationsDOIOpen Access PDF

Abstract

Mechanical degradation mechanisms are one of the leading causes of charge capacity loss in lithium-ion batteries. This study further develops a discrete element method (DEM) simulation framework, which investigates how the local contact behaviour affect the mechanical properties of the global active layer. The local microstructure consists of active particles held together by a binder domain, making up a granular medium. This study investigates the impact of the layer's global properties from the type of particle contact model. Experiments were also performed to measure size distribution and the material properties of the active material. The time dependency of the active layer, stemming from the viscoelastic binder domain, was studied in relaxation simulations, which were based on experimental measurements.

Topics & Concepts

ViscoelasticityMaterials scienceDiscrete element methodComposite materialLithium (medication)Battery (electricity)MicrostructureLayer (electronics)Relaxation (psychology)Particle (ecology)Lithium-ion batteryElectrodeMechanicsThermodynamicsChemistryPhysicsGeologyPsychologyEndocrinologySocial psychologyPower (physics)Physical chemistryOceanographyMedicineAdvancements in Battery MaterialsAdvanced Battery Technologies ResearchSupercapacitor Materials and Fabrication
Discrete element modelling of the elastic-plastic and viscoelastic properties of a lithium-ion battery electrode layer | Litcius