Litcius/Paper detail

Revealing Interface Polarization Effects on the Electrical Double Layer with Efficient Open Boundary Simulations under Potential Control

Margherita Buraschi, Andrew P. Horsfield, Clotilde S. Cucinotta

2024The Journal of Physical Chemistry Letters10 citationsDOIOpen Access PDF

Abstract

High Resolution Image Download MS PowerPoint Slide A major challenge in modeling interfacial processes in electrochemical (EC) devices is performing simulations at constant potential. This requires an open-boundary description of the electrons, so that they can enter and leave the computational cell. To enable realistic modeling of EC processes under potential control we have interfaced density functional theory with the hairy probe method in the weak coupling limit (Zauchner et al. Phys. Rev. B 2018, 97, 045116). Our implementation was systematically tested using simple parallel-plate capacitor models with pristine surfaces and a single layer of adsorbed water molecules. Remarkably, our code’s efficiency is comparable with a standard DFT calculation. We reveal that local field effects at the electrical double layer induced by the change of applied potential can significantly affect the energies of chemical steps in heterogeneous electrocatalysis. Our results demonstrate the importance of an explicit modeling of the applied potential in a simulation and provide an efficient tool to control this critical parameter.

Topics & Concepts

Polarization (electrochemistry)Density functional theoryElectrochemistryCapacitorCoupling (piping)PlanarBoundary value problemElectrochemical potentialChemical physicsComputer scienceComputational physicsMaterials scienceChemistryPhysicsComputational chemistryPhysical chemistryQuantum mechanicsElectrodeVoltageComputer graphics (images)MetallurgyElectrocatalysts for Energy ConversionMolecular Junctions and NanostructuresElectrochemical Analysis and Applications
Revealing Interface Polarization Effects on the Electrical Double Layer with Efficient Open Boundary Simulations under Potential Control | Litcius