Multi-fidelity machine learning models for accurate bandgap predictions of solids

[Display omitted] We present a multi-fidelity co-kriging statistical learning framework that combines variable-fidelity quantum mechanical calculations of bandgaps to generate a machine-learned model that enables low-cost accurate predictions of the bandgaps at the highest fidelity level. In additio...

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Bibliographic Details
Published inComputational materials science Vol. 129; pp. 156 - 163
Main Authors Pilania, G., Gubernatis, J.E., Lookman, T.
Format Journal Article
LanguageEnglish
Published Elsevier B.V 01.03.2017
Subjects
Double perovskites
Elpasolites
Information fusion
Materials informatics
Materials informatics
Double perovskites
Elpasolites
Information fusion
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Summary:[Display omitted] We present a multi-fidelity co-kriging statistical learning framework that combines variable-fidelity quantum mechanical calculations of bandgaps to generate a machine-learned model that enables low-cost accurate predictions of the bandgaps at the highest fidelity level. In addition, the adopted Gaussian process regression formulation allows us to predict the underlying uncertainties as a measure of our confidence in the predictions. Using a set of 600 elpasolite compounds as an example dataset and using semi-local and hybrid exchange correlation functionals within density functional theory as two levels of fidelities, we demonstrate the excellent learning performance of the method against actual high fidelity quantum mechanical calculations of the bandgaps. The presented statistical learning method is not restricted to bandgaps or electronic structure methods and extends the utility of high throughput property predictions in a significant way.
ISSN:0927-0256
1879-0801
DOI:10.1016/j.commatsci.2016.12.004