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Main Authors: Feng, Chiwen, Liang, Yanwei, Sun, Jiaying, Wang, Renhai, Sun, Huaijun, Dong, Huafeng
Format: Preprint
Published: 2024
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Online Access:https://arxiv.org/abs/2409.02633
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author Feng, Chiwen
Liang, Yanwei
Sun, Jiaying
Wang, Renhai
Sun, Huaijun
Dong, Huafeng
author_facet Feng, Chiwen
Liang, Yanwei
Sun, Jiaying
Wang, Renhai
Sun, Huaijun
Dong, Huafeng
contents The combination of data science and materials informatics has significantly propelled the advancement of multi-component compound synthesis research. This study employs atomic-level data to predict miscibility in binary compounds using machine learning, demonstrating the feasibility of such predictions. We have integrated experimental data from the Materials Project (MP) database and the Inorganic Crystal Structure Database (ICSD), covering 2,346 binary systems. We applied a random forest classification model to train the constructed dataset and analyze the key factors affecting the miscibility of binary systems and their significance while predicting binary systems with high synthetic potential. By employing advanced genetic algorithms on the Co-Eu system, we discovered three novel thermodynamically stable phases, CoEu8, Co3Eu2, and CoEu. This research offers valuable theoretical insights to guide experimental synthesis endeavors in binary and complex material systems.
format Preprint
id arxiv_https___arxiv_org_abs_2409_02633
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Predicting Miscibility in Binary Compounds: A Machine Learning and Genetic Algorithm Study
Feng, Chiwen
Liang, Yanwei
Sun, Jiaying
Wang, Renhai
Sun, Huaijun
Dong, Huafeng
Materials Science
Computational Physics
The combination of data science and materials informatics has significantly propelled the advancement of multi-component compound synthesis research. This study employs atomic-level data to predict miscibility in binary compounds using machine learning, demonstrating the feasibility of such predictions. We have integrated experimental data from the Materials Project (MP) database and the Inorganic Crystal Structure Database (ICSD), covering 2,346 binary systems. We applied a random forest classification model to train the constructed dataset and analyze the key factors affecting the miscibility of binary systems and their significance while predicting binary systems with high synthetic potential. By employing advanced genetic algorithms on the Co-Eu system, we discovered three novel thermodynamically stable phases, CoEu8, Co3Eu2, and CoEu. This research offers valuable theoretical insights to guide experimental synthesis endeavors in binary and complex material systems.
title Predicting Miscibility in Binary Compounds: A Machine Learning and Genetic Algorithm Study
topic Materials Science
Computational Physics
url https://arxiv.org/abs/2409.02633