Litcius/Paper detail

A semiclassical Thomas–Fermi model to tune the metallicity of electrodes in molecular simulations

Laura Scalfi, Thomas Dufils, Kyle G. Reeves, Benjamin Rotenberg, Mathieu Salanne

2020The Journal of Chemical Physics79 citationsDOIOpen Access PDF

Abstract

Spurred by the increasing needs in electrochemical energy storage devices, the electrode/electrolyte interface has received a lot of interest in recent years. Molecular dynamics simulations play a prominent role in this field since they provide a microscopic picture of the mechanisms involved. The current state-of-the-art consists of treating the electrode as a perfect conductor, precluding the possibility to analyze the effect of its metallicity on the interfacial properties. Here, we show that the Thomas-Fermi model provides a very convenient framework to account for the screening of the electric field at the interface and differentiating good metals such as gold from imperfect conductors such as graphite. All the interfacial properties are modified by screening within the metal: the capacitance decreases significantly and both the structure and dynamics of the adsorbed electrolyte are affected. The proposed model opens the door for quantitative predictions of the capacitive properties of materials for energy storage.

Topics & Concepts

Semiclassical physicsElectrodeCapacitanceChemical physicsMaterials scienceField (mathematics)Electrical conductorInterface (matter)ElectrolyteMolecular dynamicsMetallicityCapacitive sensingImperfectCondensed matter physicsElectrochemistryCurrent (fluid)Electric fieldEnergy (signal processing)Boltzmann constantPhysicsEnergy exchangeNanotechnologyStatistical physicsAdsorptionThermal conductionWater modelDynamics (music)PlatinumChemistryContext (archaeology)Computational physicsWork (physics)Electrocatalysts for Energy ConversionElectrochemical Analysis and ApplicationsSupercapacitor Materials and Fabrication