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Bibliographic Details
Main Authors: Gharakhanyan, Vahe, Wirth, Luke J., Torres, Jose A. Garrido, Eisenberg, Ethan, Wang, Ting, Trinkle, Dallas R., Chatterjee, Snigdhansu, Urban, Alexander
Format: Preprint
Published: 2024
Subjects:
Online Access:https://arxiv.org/abs/2403.03092
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author Gharakhanyan, Vahe
Wirth, Luke J.
Torres, Jose A. Garrido
Eisenberg, Ethan
Wang, Ting
Trinkle, Dallas R.
Chatterjee, Snigdhansu
Urban, Alexander
author_facet Gharakhanyan, Vahe
Wirth, Luke J.
Torres, Jose A. Garrido
Eisenberg, Ethan
Wang, Ting
Trinkle, Dallas R.
Chatterjee, Snigdhansu
Urban, Alexander
contents The melting temperature is important for materials design because of its relationship with thermal stability, synthesis, and processing conditions. Current empirical and computational melting point estimation techniques are limited in scope, computational feasibility, or interpretability. We report the development of a machine learning methodology for predicting melting temperatures of binary ionic solid materials. We evaluated different machine-learning models trained on a data set of the melting points of 476 non-metallic crystalline binary compounds, using materials embeddings constructed from elemental properties and density-functional theory calculations as model inputs. A direct supervised-learning approach yields a mean absolute error of around 180~K but suffers from low interpretability. We find that the fidelity of predictions can further be improved by introducing an additional unsupervised-learning step that first classifies the materials before the melting-point regression. Not only does this two-step model exhibit improved accuracy, but the approach also provides a level of interpretability with insights into feature importance and different types of melting that depend on the specific atomic bonding inside a material. Motivated by this finding, we used a symbolic learning approach to find interpretable physical models for the melting temperature, which recovered the best-performing features from both prior models and provided additional interpretability.
format Preprint
id arxiv_https___arxiv_org_abs_2403_03092
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Discovering Melting Temperature Prediction Models of Inorganic Solids by Combining Supervised and Unsupervised Learning
Gharakhanyan, Vahe
Wirth, Luke J.
Torres, Jose A. Garrido
Eisenberg, Ethan
Wang, Ting
Trinkle, Dallas R.
Chatterjee, Snigdhansu
Urban, Alexander
Materials Science
The melting temperature is important for materials design because of its relationship with thermal stability, synthesis, and processing conditions. Current empirical and computational melting point estimation techniques are limited in scope, computational feasibility, or interpretability. We report the development of a machine learning methodology for predicting melting temperatures of binary ionic solid materials. We evaluated different machine-learning models trained on a data set of the melting points of 476 non-metallic crystalline binary compounds, using materials embeddings constructed from elemental properties and density-functional theory calculations as model inputs. A direct supervised-learning approach yields a mean absolute error of around 180~K but suffers from low interpretability. We find that the fidelity of predictions can further be improved by introducing an additional unsupervised-learning step that first classifies the materials before the melting-point regression. Not only does this two-step model exhibit improved accuracy, but the approach also provides a level of interpretability with insights into feature importance and different types of melting that depend on the specific atomic bonding inside a material. Motivated by this finding, we used a symbolic learning approach to find interpretable physical models for the melting temperature, which recovered the best-performing features from both prior models and provided additional interpretability.
title Discovering Melting Temperature Prediction Models of Inorganic Solids by Combining Supervised and Unsupervised Learning
topic Materials Science
url https://arxiv.org/abs/2403.03092