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Dynamic density functional theory for the charging of electric double layer capacitors

Ke Ma, Mathijs Janssen, Cheng Lian, René van Roij

2022The Journal of Chemical Physics23 citationsDOIOpen Access PDF

Abstract

We consider the charging of a model capacitor comprised of two planar electrodes and an electrolyte. Upon switching on a voltage difference, electric double layers build up in this setup, which we characterize with a classical dynamic density functional theory (DDFT) that accounts for electrostatic correlations and for molecular excluded volume of finite-sized ions and solvent molecules. Our DDFT predicts the electrode charge Q(t) to form exponentially with two timescales: at early times, the system relaxes on the RC time, namely, λDL/[D(2 + σ/λD)], with λD being the Debye length, L being the electrode separation, σ being the ion diameter, and D being the ionic diffusivity. Contrasting an earlier DDFT study, this early-time response does not depend on the applied potential. At late times, the capacitor relaxes with a relaxation time proportional to the diffusion time L2/D.

Topics & Concepts

ElectrolyteCapacitorElectrodeIonMaterials scienceDebye lengthDiffusionDensity functional theoryRelaxation (psychology)Thermal diffusivityIonic bondingChemical physicsVoltageCharge densityMolecular physicsAnalytical Chemistry (journal)ChemistryThermodynamicsPhysicsComputational chemistryPhysical chemistryPsychologyQuantum mechanicsSocial psychologyChromatographyOrganic chemistryElectrochemical Analysis and ApplicationsElectrostatics and Colloid InteractionsFuel Cells and Related Materials
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