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Auteur principal: Phuntsho, Sonam
Format: Preprint
Publié: 2024
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Accès en ligne:https://arxiv.org/abs/2412.09294
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author Phuntsho, Sonam
author_facet Phuntsho, Sonam
contents This study investigates the molecular-level self-assembly behavior of seven functionalized diamondoids, examining how diverse substituents influence structural organization, thermal stability, and aggregate morphology. Using a combination of density functional theory for initial geometry optimization and molecular dynamics simulations, we explored radial distribution functions, thermal fragmentation temperatures, and radii of gyration for each system. Our results reveal that hydrogen-bonding and polar functional groups (e.g., amino, hydroxy) foster well-defined, ordered assemblies, while bulkier or less interactive substituents (e.g., phenyl, methoxy) lead to more open, amorphous aggregates. Thermal stability strongly depends on substituent chemistry: complex, bulky groups or heteroatom-rich functionalities confer enhanced resistance to fragmentation at high temperatures, whereas simpler groups destabilize the assembly at lower temperatures. Radii of gyration further show that substituent size and polarity can fine-tune cluster compactness. These findings provide critical insights for designing diamondoid-based nanomaterials with tailored structural properties, thermal endurance, and functional performance in advanced technological applications.
format Preprint
id arxiv_https___arxiv_org_abs_2412_09294
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Influence of Functional Group on the Self Assembly of Diamondoids: A Molecular Dynamics Study
Phuntsho, Sonam
Mesoscale and Nanoscale Physics
This study investigates the molecular-level self-assembly behavior of seven functionalized diamondoids, examining how diverse substituents influence structural organization, thermal stability, and aggregate morphology. Using a combination of density functional theory for initial geometry optimization and molecular dynamics simulations, we explored radial distribution functions, thermal fragmentation temperatures, and radii of gyration for each system. Our results reveal that hydrogen-bonding and polar functional groups (e.g., amino, hydroxy) foster well-defined, ordered assemblies, while bulkier or less interactive substituents (e.g., phenyl, methoxy) lead to more open, amorphous aggregates. Thermal stability strongly depends on substituent chemistry: complex, bulky groups or heteroatom-rich functionalities confer enhanced resistance to fragmentation at high temperatures, whereas simpler groups destabilize the assembly at lower temperatures. Radii of gyration further show that substituent size and polarity can fine-tune cluster compactness. These findings provide critical insights for designing diamondoid-based nanomaterials with tailored structural properties, thermal endurance, and functional performance in advanced technological applications.
title Influence of Functional Group on the Self Assembly of Diamondoids: A Molecular Dynamics Study
topic Mesoscale and Nanoscale Physics
url https://arxiv.org/abs/2412.09294