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Paper detail

Three-dimensional experimental-scale phase-field modelling of dendrite formation in rechargeable lithium-metal batteries

We perform phase-field simulations of the electrodeposition process that forms dendrites within metal-anode batteries including anisotropic representation. We describe the evolution of a phase field, the lithium-ion concentration, and an electric potential, during a battery charge cycle, solving equations using time-marching algorithms with automatic time-step adjustment and implemented on an open-source finite element library. A modified lithium crystal surface anisotropy representation for phase-field electrodeposition model is proposed and evaluated through different numerical tests, exhibiting low sensitivity to the numerical parameters. Change of dendritic morphological behaviour is captured by a variation of the simulated inter-electrode distance. A set of simulations are presented to validate the proposed formulation, showing their agreement with experimentally-observed lithium dendrite growth rates, and morphologies reported in the literature.

preprint2022arXivOpen access
Marcos E. ArguelloNicolas A. LabandaVictor M. CaloMonica GumulyaRanjeet UtikarJos Derksen
physics.app-ph
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Marcos E. ArguelloNicolas A. LabandaVictor M. CaloMonica GumulyaRanjeet UtikarJos Derksen

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