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Autori principali: Yamazaki, Kosuke, Shiga, Takuma, Shiraishi, Kumpei, Minamitani, Emi
Natura: Preprint
Pubblicazione: 2025
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Accesso online:https://arxiv.org/abs/2512.13112
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author Yamazaki, Kosuke
Shiga, Takuma
Shiraishi, Kumpei
Minamitani, Emi
author_facet Yamazaki, Kosuke
Shiga, Takuma
Shiraishi, Kumpei
Minamitani, Emi
contents Understanding and predicting thermal transport in disordered materials remains a significant challenge due to the absence of periodicity and the complex nature of medium-range structural motifs. In this work, we investigate amorphous graphene and demonstrate that persistent homology, a topological data analysis technique, can serve as a physically interpretable structural descriptor for predicting thermal conductivity. We first show that ridge regression using persistent homology descriptors achieves high prediction accuracy. To gain physical insight into the prediction process, we perform inverse analysis by mapping the regression coefficients back onto the persistence diagrams. This reveals that distorted hexagonal and triangular motifs are strongly correlated with reduced thermal conductivity. A further comparison with the spatial distribution of localized vibrational modes supports the physical interpretation that these motifs suppress thermal transport. Our findings highlight that persistent homology not only enables accurate prediction of physical properties but also uncovers meaningful structure-property relationships in two-dimensional amorphous materials. This approach offers a promising framework for interpretable machine-learning models in materials science.
format Preprint
id arxiv_https___arxiv_org_abs_2512_13112
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Topological descriptor for interpretable thermal transport prediction in amorphous graphene
Yamazaki, Kosuke
Shiga, Takuma
Shiraishi, Kumpei
Minamitani, Emi
Materials Science
Understanding and predicting thermal transport in disordered materials remains a significant challenge due to the absence of periodicity and the complex nature of medium-range structural motifs. In this work, we investigate amorphous graphene and demonstrate that persistent homology, a topological data analysis technique, can serve as a physically interpretable structural descriptor for predicting thermal conductivity. We first show that ridge regression using persistent homology descriptors achieves high prediction accuracy. To gain physical insight into the prediction process, we perform inverse analysis by mapping the regression coefficients back onto the persistence diagrams. This reveals that distorted hexagonal and triangular motifs are strongly correlated with reduced thermal conductivity. A further comparison with the spatial distribution of localized vibrational modes supports the physical interpretation that these motifs suppress thermal transport. Our findings highlight that persistent homology not only enables accurate prediction of physical properties but also uncovers meaningful structure-property relationships in two-dimensional amorphous materials. This approach offers a promising framework for interpretable machine-learning models in materials science.
title Topological descriptor for interpretable thermal transport prediction in amorphous graphene
topic Materials Science
url https://arxiv.org/abs/2512.13112