Litcius/Paper detail

Molecular understanding of the Helmholtz capacitance difference between Cu(100) and graphene electrodes

Xiang-Ying Li, Xiangfeng Jin, Xiaohui Yang, Xue Wang, Jiabo Le, Jun Cheng

2023The Journal of Chemical Physics33 citationsDOI

Abstract

Unraveling the origin of Helmholtz capacitance is of paramount importance for understanding the interfacial structure and electrostatic potential distribution of electric double layers (EDL). In this work, we combined the methods of ab initio molecular dynamics and classical molecular dynamics and modeled electrified Cu(100)/electrolyte and graphene/electrolyte interfaces for comparison. It was proposed that the Helmholtz capacitance is composed of three parts connected in series: the usual solvent capacitance, water chemisorption induced capacitance, and Pauling repulsion caused gap capacitance. We found the Helmholtz capacitance of graphene is significantly lower than that of Cu(100), which was attributed to two intrinsic factors. One is that graphene has a wider gap layer at interface, and the other is that graphene is less active for water chemisorption. Finally, based on our findings, we provide suggestions for how to increase the EDL capacitance of graphene-based materials in future work, and we also suggest that the new understanding of the potential distribution across the Helmholtz layer may help explain some experimental phenomena of electrocatalysis.

Topics & Concepts

GrapheneCapacitanceQuantum capacitanceHelmholtz free energyElectrolyteMaterials scienceChemical physicsChemisorptionMolecular dynamicsDifferential capacitanceWork (physics)ElectrodeCondensed matter physicsNanotechnologyChemistryComputational chemistryPhysicsThermodynamicsAdsorptionPhysical chemistryElectrochemical Analysis and ApplicationsGraphene research and applicationsMolecular Junctions and Nanostructures