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Main Authors: Ponomarova, Svitlana, Ponomarov, Oleksandr, Koval, Yurii
Format: Preprint
Published: 2025
Subjects:
Online Access:https://arxiv.org/abs/2509.17843
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author Ponomarova, Svitlana
Ponomarov, Oleksandr
Koval, Yurii
author_facet Ponomarova, Svitlana
Ponomarov, Oleksandr
Koval, Yurii
contents This study presents a machine learning approach to predict the Curie temperature in binary alloys, specifically focusing on the Fe-Pt, Fe-Ni, Fe-Pd, and Co-Pt compounds within a concentration range of 10 to 90 atomic percent. The optimal mathematical algorithm for this task is the Voting Ensemble algorithm, which combines the predictions from multiple individual models to produce a final prediction. The results are validated against classical methods for calculating Curie temperatures. The experimental findings indicate that factors such as external pressure, atomic ordering, and alloy composition have a significant influence on the Curie temperatures in all examined binary systems. These factors can be leveraged to design alloys with specific Curie temperatures. Moreover, the proposed features, feature analysis algorithms, and computational methods pave the way for advancements across various materials, including ternary alloys, bulk materials, and nanomaterials, inspiring innovation in the field.
format Preprint
id arxiv_https___arxiv_org_abs_2509_17843
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Machine Learning Approach to Predict Curie Temperature in Binary Alloys
Ponomarova, Svitlana
Ponomarov, Oleksandr
Koval, Yurii
Materials Science
80-00, 80-04, 80-10
This study presents a machine learning approach to predict the Curie temperature in binary alloys, specifically focusing on the Fe-Pt, Fe-Ni, Fe-Pd, and Co-Pt compounds within a concentration range of 10 to 90 atomic percent. The optimal mathematical algorithm for this task is the Voting Ensemble algorithm, which combines the predictions from multiple individual models to produce a final prediction. The results are validated against classical methods for calculating Curie temperatures. The experimental findings indicate that factors such as external pressure, atomic ordering, and alloy composition have a significant influence on the Curie temperatures in all examined binary systems. These factors can be leveraged to design alloys with specific Curie temperatures. Moreover, the proposed features, feature analysis algorithms, and computational methods pave the way for advancements across various materials, including ternary alloys, bulk materials, and nanomaterials, inspiring innovation in the field.
title Machine Learning Approach to Predict Curie Temperature in Binary Alloys
topic Materials Science
80-00, 80-04, 80-10
url https://arxiv.org/abs/2509.17843