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materials science

Machine Learning Models for the Lattice Thermal Conductivity Prediction of Inorganic Materials

arXiv:1906.06378

summary

The paper presents a machine‑learning model, based on Gaussian process regression and advanced feature engineering, that can instantly predict the lattice thermal conductivity of inorganic solids using a dataset of experimental measurements.

Abstract

The lattice thermal conductivity ($κ_{\rm L} $) is a critical property of thermoelectrics, thermal barrier coating materials and semiconductors. While accurate empirical measurements of $κ_{\rm L} $ are extremely challenging, it is usually approximated through computational approaches, such as semi-empirical models, Green-Kubo formalism coupled with molecular dynamics simulations, and first-principles based methods. However, these theoretical methods are not only limited in terms of their accuracy, but sometimes become computationally intractable owing to their cost. Thus, in this work, we build a machine learning (ML)-based model to accurately and instantly predict $κ_{\rm L}$ of inorganic materials, using a benchmark data set of experimentally measured $κ_{\rm L} $ of about 100 inorganic solids. We use advanced and universal feature engineering techniques along with the Gaussian process regression algorithm, and compare the performance of our ML model with past theoretical works. The trained ML model is not only helpful for rational design and screening of novel materials, but we also identify key features governing the thermal transport behavior in non-metals.

Topics & keywords

#lattice thermal conductivity#machine learning#materials screening#feature engineering#gaussian process regressionGaussian process regressionfeature engineeringexperimental thermal conductivity datasetinorganic solidsthermoelectrics