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Autores principales: Wang, Yisen, Huang, Liang
Formato: Preprint
Publicado: 2024
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Acceso en línea:https://arxiv.org/abs/2403.06442
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author Wang, Yisen
Huang, Liang
author_facet Wang, Yisen
Huang, Liang
contents As the essential cause of the intrinsic dissipation that limits the quality of graphene nanoresonators, intermodal energy transfer is also a key issue in thermalization dynamics. Typically systems with larger initial energy demand shorter time to be thermalized. However, we find quantitatively that instead of becoming shorter, the equipartition time of the graphene nanoresonator can increase abruptly by one order of magnitude. This thermalization frustration emerges due to the partition of the normal modes based on the hierarchical symmetry, and a sensitive on-off switching of the energy flow channels between symmetry classes controlled by Mathieu instabilities. The results uncover the decisive roles of symmetry in the thermalization at the nanoscale, and may also lead to strategies for improving the performance of graphene nanoresonators.
format Preprint
id arxiv_https___arxiv_org_abs_2403_06442
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Symmetry Hierarchy and Thermalization Frustration in Graphene Nanoresonators
Wang, Yisen
Huang, Liang
Statistical Mechanics
As the essential cause of the intrinsic dissipation that limits the quality of graphene nanoresonators, intermodal energy transfer is also a key issue in thermalization dynamics. Typically systems with larger initial energy demand shorter time to be thermalized. However, we find quantitatively that instead of becoming shorter, the equipartition time of the graphene nanoresonator can increase abruptly by one order of magnitude. This thermalization frustration emerges due to the partition of the normal modes based on the hierarchical symmetry, and a sensitive on-off switching of the energy flow channels between symmetry classes controlled by Mathieu instabilities. The results uncover the decisive roles of symmetry in the thermalization at the nanoscale, and may also lead to strategies for improving the performance of graphene nanoresonators.
title Symmetry Hierarchy and Thermalization Frustration in Graphene Nanoresonators
topic Statistical Mechanics
url https://arxiv.org/abs/2403.06442