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Main Authors: Riebesell, Janosh, Surta, T. Wesley, Goodall, Rhys, Gaultois, Michael, Lee, Alpha A
Format: Preprint
Published: 2024
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Online Access:https://arxiv.org/abs/2401.05848
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author Riebesell, Janosh
Surta, T. Wesley
Goodall, Rhys
Gaultois, Michael
Lee, Alpha A
author_facet Riebesell, Janosh
Surta, T. Wesley
Goodall, Rhys
Gaultois, Michael
Lee, Alpha A
contents Materials with high-dielectric constant easily polarize under external electric fields, allowing them to perform essential functions in many modern electronic devices. Their practical utility is determined by two conflicting properties: high dielectric constants tend to occur in materials with narrow band gaps, limiting the operating voltage before dielectric breakdown. We present a high-throughput workflow that combines element substitution, ML pre-screening, ab initio simulation and human expert intuition to efficiently explore the vast space of unknown materials for potential dielectrics, leading to the synthesis and characterization of two novel dielectric materials, CsTaTeO6 and Bi2Zr2O7. Our key idea is to deploy ML in a multi-objective optimization setting with concave Pareto front. While usually considered more challenging than single-objective optimization, we argue and show preliminary evidence that the $1/x$-correlation between band gap and permittivity in fact makes the task more amenable to ML methods by allowing separate models for band gap and permittivity to each operate in regions of good training support while still predicting materials of exceptional merit. To our knowledge, this is the first instance of successful ML-guided multi-objective materials optimization achieving experimental synthesis and characterization. CsTaTeO6 is a structure generated via element substitution not present in our reference data sources, thus exemplifying successful de-novo materials design. Meanwhile, we report the first high-purity synthesis and dielectric characterization of Bi2Zr2O7 with a band gap of 2.27 eV and a permittivity of 20.5, meeting all target metrics of our multi-objective search.
format Preprint
id arxiv_https___arxiv_org_abs_2401_05848
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Pushing the Pareto front of band gap and permittivity: ML-guided search for dielectric materials
Riebesell, Janosh
Surta, T. Wesley
Goodall, Rhys
Gaultois, Michael
Lee, Alpha A
Materials Science
Artificial Intelligence
Machine Learning
Chemical Physics
Materials with high-dielectric constant easily polarize under external electric fields, allowing them to perform essential functions in many modern electronic devices. Their practical utility is determined by two conflicting properties: high dielectric constants tend to occur in materials with narrow band gaps, limiting the operating voltage before dielectric breakdown. We present a high-throughput workflow that combines element substitution, ML pre-screening, ab initio simulation and human expert intuition to efficiently explore the vast space of unknown materials for potential dielectrics, leading to the synthesis and characterization of two novel dielectric materials, CsTaTeO6 and Bi2Zr2O7. Our key idea is to deploy ML in a multi-objective optimization setting with concave Pareto front. While usually considered more challenging than single-objective optimization, we argue and show preliminary evidence that the $1/x$-correlation between band gap and permittivity in fact makes the task more amenable to ML methods by allowing separate models for band gap and permittivity to each operate in regions of good training support while still predicting materials of exceptional merit. To our knowledge, this is the first instance of successful ML-guided multi-objective materials optimization achieving experimental synthesis and characterization. CsTaTeO6 is a structure generated via element substitution not present in our reference data sources, thus exemplifying successful de-novo materials design. Meanwhile, we report the first high-purity synthesis and dielectric characterization of Bi2Zr2O7 with a band gap of 2.27 eV and a permittivity of 20.5, meeting all target metrics of our multi-objective search.
title Pushing the Pareto front of band gap and permittivity: ML-guided search for dielectric materials
topic Materials Science
Artificial Intelligence
Machine Learning
Chemical Physics
url https://arxiv.org/abs/2401.05848