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Autori principali: Bizot, Quentin, Tamura, Ryo, Deffrennes, Guillaume
Natura: Preprint
Pubblicazione: 2025
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Accesso online:https://arxiv.org/abs/2507.20885
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author Bizot, Quentin
Tamura, Ryo
Deffrennes, Guillaume
author_facet Bizot, Quentin
Tamura, Ryo
Deffrennes, Guillaume
contents The enthalpy of mixing in the liquid phase is an important property for predicting phase formation in alloys. It can be estimated in a large compositional space from pair wise interactions between elements, for which machine learning has recently provided the most accurate predictions. Further improvements requires acquiring high quality data in liquids where models are poorly constrained. In this study, we propose an active learning approach to identify in which liquids additional data are most needed to improve an initial dataset that covers over 400 binary liquids. We identify a critical need for new data on liquids containing refractory elements, which we address by performing ab initio molecular dynamics simulations for 29 equimolar alloys of Ir, Os, Re and W. This enables more accurate predictions of the enthalpy of mixing, and we discuss the trends obtained for refractory elements of period 6. We use clustering analysis to interpret the results of active learning and to explore how our features can be linked to Miedema's semi empirical theory.
format Preprint
id arxiv_https___arxiv_org_abs_2507_20885
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Active Learning for Predicting the Enthalpy of Mixing inBinary Liquids Based on Ab Initio Molecular Dynamics
Bizot, Quentin
Tamura, Ryo
Deffrennes, Guillaume
Materials Science
Computational Physics
The enthalpy of mixing in the liquid phase is an important property for predicting phase formation in alloys. It can be estimated in a large compositional space from pair wise interactions between elements, for which machine learning has recently provided the most accurate predictions. Further improvements requires acquiring high quality data in liquids where models are poorly constrained. In this study, we propose an active learning approach to identify in which liquids additional data are most needed to improve an initial dataset that covers over 400 binary liquids. We identify a critical need for new data on liquids containing refractory elements, which we address by performing ab initio molecular dynamics simulations for 29 equimolar alloys of Ir, Os, Re and W. This enables more accurate predictions of the enthalpy of mixing, and we discuss the trends obtained for refractory elements of period 6. We use clustering analysis to interpret the results of active learning and to explore how our features can be linked to Miedema's semi empirical theory.
title Active Learning for Predicting the Enthalpy of Mixing inBinary Liquids Based on Ab Initio Molecular Dynamics
topic Materials Science
Computational Physics
url https://arxiv.org/abs/2507.20885