Litcius/Paper detail

Software for Evaluating Long-Range Electrostatic Interactions Based on the Ewald Summation and Its Application to Electrochemical Energy Storage Materials

Wei Shi, Bing He, Bowei Pu, Yuan Ren, Maxim Avdeev, Siqi Shi

2022The Journal of Physical Chemistry A23 citationsDOI

Abstract

Electrochemical characteristics such as open-circuit voltage and ionic conductivity of electrochemical energy storage materials are easily affected, typically negatively, by mobile ion/vacancy ordering. Ordered phases can be identified based on the lattice gas model and electrostatic energy screening. However, the evaluation of long-range electrostatic energy is not straightforward because of the conditional convergence. The Ewald method decomposes the electrostatic energy into a real space part and a reciprocal space part, achieving a fast convergence in each. Due to its high computational efficiency, Ewald-based techniques are widely used in analyzing characteristics of electrochemical energy storage materials. In this work, we present software not only integrating Ewald techniques for two-dimensional and three-dimensional periodic systems but also combining the Ewald method with the lattice matching algorithm and bond valence. It is aimed to become a useful tool for screening stable structures and interfaces and identifying the ionic transport channels of cation conductors.

Topics & Concepts

Ewald summationLattice energyIonic bondingElectrostaticsElectric potential energyLattice (music)ElectrochemistryReciprocal latticeComputer scienceStatistical physicsMaterials scienceConvergence (economics)Chemical physicsChemistryIonEnergy (signal processing)PhysicsComputational chemistryMolecular dynamicsPhysical chemistryElectrodeCrystal structureQuantum mechanicsCrystallographyEconomicsAcousticsEconomic growthDiffractionMachine Learning in Materials ScienceFuel Cells and Related MaterialsElectrocatalysts for Energy Conversion