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Main Authors: Liu, Yanjun, Jovanovic, Milena, Mallayya, Krishnanand, Maddox, Wesley J., Wilson, Andrew Gordon, Klemenz, Sebastian, Schoop, Leslie M., Kim, Eun-Ah
Format: Preprint
Published: 2023
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Online Access:https://arxiv.org/abs/2312.02796
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author Liu, Yanjun
Jovanovic, Milena
Mallayya, Krishnanand
Maddox, Wesley J.
Wilson, Andrew Gordon
Klemenz, Sebastian
Schoop, Leslie M.
Kim, Eun-Ah
author_facet Liu, Yanjun
Jovanovic, Milena
Mallayya, Krishnanand
Maddox, Wesley J.
Wilson, Andrew Gordon
Klemenz, Sebastian
Schoop, Leslie M.
Kim, Eun-Ah
contents The advent of material databases provides an unprecedented opportunity to uncover predictive descriptors for emergent material properties from vast data space. However, common reliance on high-throughput ab initio data necessarily inherits limitations of such data: mismatch with experiments. On the other hand, experimental decisions are often guided by an expert's intuition honed from experiences that are rarely articulated. We propose using machine learning to "bottle" such operational intuition into quantifiable descriptors using expertly curated measurement-based data. We introduce "Materials Expert-Artificial Intelligence" (ME-AI) to encapsulate and articulate this human intuition. As a first step towards such a program, we focus on the topological semimetal (TSM) among square-net materials as the property inspired by the expert-identified descriptor based on structural information: the tolerance factor. We start by curating a dataset encompassing 12 primary features of 879 square-net materials, using experimental data whenever possible. We then use Dirichlet-based Gaussian process regression using a specialized kernel to reveal composite descriptors for square-net topological semimetals. The ME-AI learned descriptors independently reproduce expert intuition and expand upon it. Specifically, new descriptors point to hypervalency as a critical chemical feature predicting TSM within square-net compounds. Our success with a carefully defined problem points to the "machine bottling human insight" approach as promising for machine learning-aided material discovery.
format Preprint
id arxiv_https___arxiv_org_abs_2312_02796
institution arXiv
publishDate 2023
record_format arxiv
spellingShingle Materials Expert-Artificial Intelligence for Materials Discovery
Liu, Yanjun
Jovanovic, Milena
Mallayya, Krishnanand
Maddox, Wesley J.
Wilson, Andrew Gordon
Klemenz, Sebastian
Schoop, Leslie M.
Kim, Eun-Ah
Materials Science
Strongly Correlated Electrons
Machine Learning
Data Analysis, Statistics and Probability
The advent of material databases provides an unprecedented opportunity to uncover predictive descriptors for emergent material properties from vast data space. However, common reliance on high-throughput ab initio data necessarily inherits limitations of such data: mismatch with experiments. On the other hand, experimental decisions are often guided by an expert's intuition honed from experiences that are rarely articulated. We propose using machine learning to "bottle" such operational intuition into quantifiable descriptors using expertly curated measurement-based data. We introduce "Materials Expert-Artificial Intelligence" (ME-AI) to encapsulate and articulate this human intuition. As a first step towards such a program, we focus on the topological semimetal (TSM) among square-net materials as the property inspired by the expert-identified descriptor based on structural information: the tolerance factor. We start by curating a dataset encompassing 12 primary features of 879 square-net materials, using experimental data whenever possible. We then use Dirichlet-based Gaussian process regression using a specialized kernel to reveal composite descriptors for square-net topological semimetals. The ME-AI learned descriptors independently reproduce expert intuition and expand upon it. Specifically, new descriptors point to hypervalency as a critical chemical feature predicting TSM within square-net compounds. Our success with a carefully defined problem points to the "machine bottling human insight" approach as promising for machine learning-aided material discovery.
title Materials Expert-Artificial Intelligence for Materials Discovery
topic Materials Science
Strongly Correlated Electrons
Machine Learning
Data Analysis, Statistics and Probability
url https://arxiv.org/abs/2312.02796