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Autori principali: Zhang, Bohan, Liu, Biyuan, Ying, Penghua, Chen, Zherui, Wang, Yanzhou, Zhang, Yonglin, Dong, Haikuan, Yang, Jinglei, Fan, Zheyong
Natura: Preprint
Pubblicazione: 2025
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Accesso online:https://arxiv.org/abs/2512.21490
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author Zhang, Bohan
Liu, Biyuan
Ying, Penghua
Chen, Zherui
Wang, Yanzhou
Zhang, Yonglin
Dong, Haikuan
Yang, Jinglei
Fan, Zheyong
author_facet Zhang, Bohan
Liu, Biyuan
Ying, Penghua
Chen, Zherui
Wang, Yanzhou
Zhang, Yonglin
Dong, Haikuan
Yang, Jinglei
Fan, Zheyong
contents Graphene oxide (GO) exhibits rich chemical heterogeneity that strongly influences its structural, thermal, and mechanical properties, yet quantitatively linking reduction chemistry to heat transport remains challenging. In this work, we develop a machine-learned neuroevolution potential (NEP) trained on an existing density functional theory dataset (\textit{Angew.\ Chem.\ Int.\ Ed.}, \textbf{63} , e202410088 (2024)), achieving reasonable accuracy at a computational cost much lower than the existing machine-learned and empirical potentials. Leveraging this potential, we perform large-scale molecular dynamics (MD) simulations to model the thermal reduction of GO across realistic structural domains. Using the homogeneous nonequilibrium MD method with a proper quantum-statistical correction scheme, we find that reduced GO exhibits strongly suppressed thermal conductivities, ranging from a few to tens of Wm$^{-1}$K$^{-1}$, substantially lower than pristine GO without defects and far below graphene. Moreover, the thermal conductivity of reduced GO increases moderately with increasing OH/O ratio, except at the highest oxidation level (O/C=0.5) where this trend inverts, while decreasing significantly with increasing O/C ratio, a trend strongly correlated with the fraction of recovered graphene-like structures. Our work provides a computationally tractable and predictive atomistic machine learning framework for exploring how chemical structure governs heat transport in heterogeneous carbon materials.
format Preprint
id arxiv_https___arxiv_org_abs_2512_21490
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Thermal conductivities of monolayer graphene oxide from machine learning molecular dynamics simulations
Zhang, Bohan
Liu, Biyuan
Ying, Penghua
Chen, Zherui
Wang, Yanzhou
Zhang, Yonglin
Dong, Haikuan
Yang, Jinglei
Fan, Zheyong
Chemical Physics
Graphene oxide (GO) exhibits rich chemical heterogeneity that strongly influences its structural, thermal, and mechanical properties, yet quantitatively linking reduction chemistry to heat transport remains challenging. In this work, we develop a machine-learned neuroevolution potential (NEP) trained on an existing density functional theory dataset (\textit{Angew.\ Chem.\ Int.\ Ed.}, \textbf{63} , e202410088 (2024)), achieving reasonable accuracy at a computational cost much lower than the existing machine-learned and empirical potentials. Leveraging this potential, we perform large-scale molecular dynamics (MD) simulations to model the thermal reduction of GO across realistic structural domains. Using the homogeneous nonequilibrium MD method with a proper quantum-statistical correction scheme, we find that reduced GO exhibits strongly suppressed thermal conductivities, ranging from a few to tens of Wm$^{-1}$K$^{-1}$, substantially lower than pristine GO without defects and far below graphene. Moreover, the thermal conductivity of reduced GO increases moderately with increasing OH/O ratio, except at the highest oxidation level (O/C=0.5) where this trend inverts, while decreasing significantly with increasing O/C ratio, a trend strongly correlated with the fraction of recovered graphene-like structures. Our work provides a computationally tractable and predictive atomistic machine learning framework for exploring how chemical structure governs heat transport in heterogeneous carbon materials.
title Thermal conductivities of monolayer graphene oxide from machine learning molecular dynamics simulations
topic Chemical Physics
url https://arxiv.org/abs/2512.21490