Litcius/Paper detail

Modeling the dielectric constants of crystals using machine learning

Kazuki Morita, Daniel W. Davies, Keith T. Butler, Aron Walsh

2020The Journal of Chemical Physics63 citationsDOIOpen Access PDF

Abstract

The relative permittivity of a crystal is a fundamental property that links microscopic chemical bonding to macroscopic electromagnetic response. Multiple models, including analytical, numerical, and statistical descriptions, have been made to understand and predict dielectric behavior. Analytical models are often limited to a particular type of compound, whereas machine learning (ML) models often lack interpretability. Here, we combine supervised ML, density functional perturbation theory, and analysis based on game theory to predict and explain the physical trends in optical dielectric constants of crystals. Two ML models, support vector regression and deep neural networks, were trained on a dataset of 1364 dielectric constants. Analysis of Shapley additive explanations of the ML models reveals that they recover correlations described by textbook Clausius-Mossotti and Penn models, which gives confidence in their ability to describe physical behavior, while providing superior predictive power.

Topics & Concepts

DielectricMachine learningArtificial intelligenceArtificial neural networkSupport vector machinePermittivityComputer scienceProperty (philosophy)RegressionRegression analysisPerturbation (astronomy)Supervised learningStatistical physicsDielectric permittivityMathematicsRelative permittivityPerturbation theory (quantum mechanics)Materials scienceStatistical modelLinear regressionCondensed matter physicsDeep learningAlgorithmPattern recognition (psychology)Physical propertyPredictive modellingLasso (programming language)Characterization (materials science)PhysicsConstant (computer programming)Statistical analysisStatistical learningLight scatteringMathematical modelMachine Learning in Materials ScienceX-ray Diffraction in CrystallographyCrystallography and molecular interactions