Litcius/Paper detail

Computational and training requirements for interatomic potential based on artificial neural network for estimating low thermal conductivity of silver chalcogenides

Kohei Shimamura, Yusuke Takeshita, Shogo Fukushima, Akihide Koura, Fuyuki Shimojo

2020The Journal of Chemical Physics21 citationsDOI

Abstract

We examined the estimation of thermal conductivity through molecular dynamics simulations for a superionic conductor, α-Ag2Se, using the interatomic potential based on an artificial neural network (ANN potential). The training data were created using the existing empirical potential of Ag2Se to help find suitable computational and training requirements for the ANN potential, with the intent to apply them to first-principles calculations. The thermal conductivities calculated using different definitions of heat flux were compared, and the effect of explicit long-range Coulomb interaction on the conductivities was investigated. We clarified that using a rigorous heat flux formula for the ANN potential, even for highly ionic α-Ag2Se, the resulting thermal conductivity was reasonably consistent with the reference value without explicitly considering Coulomb interaction. It was found that ANN training including the virial term played an important role in reducing the dependency of thermal conductivity on the initial values of the weight parameters of the ANN.

Topics & Concepts

Thermal conductivityArtificial neural networkConductorInteratomic potentialCoulombHeat fluxMaterials scienceIonic conductivityRange (aeronautics)ThermodynamicsComputer scienceStatistical physicsMolecular dynamicsMachine learningArtificial intelligenceChemistryPhysicsElectronComputational chemistryHeat transferPhysical chemistryQuantum mechanicsComposite materialElectrolyteElectrodeMachine Learning in Materials ScienceAdvanced Thermoelectric Materials and DevicesChalcogenide Semiconductor Thin Films