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Hauptverfasser: Gumpert, Fabian, Eitel, Dominik, Kottas, Olaf, Helbig, Uta, Lohbreier, Jan
Format: Preprint
Veröffentlicht: 2025
Schlagworte:
Online-Zugang:https://arxiv.org/abs/2501.17087
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author Gumpert, Fabian
Eitel, Dominik
Kottas, Olaf
Helbig, Uta
Lohbreier, Jan
author_facet Gumpert, Fabian
Eitel, Dominik
Kottas, Olaf
Helbig, Uta
Lohbreier, Jan
contents This study presents a simulation approach for three-dimensional nanotube networks using cubic and tetragonal unit cells to enhance modeling efficiency. A random-walk algorithm was developed to generate these networks, which were analyzed in a Finite Element Method (FEM) simulation to assess their electrical conductivity. The percolation probability as a function of the nanotube filling factor can be derived from these simulation results. It is found that smaller tetragonal unit cells can replicate the behavior of larger networks with significantly reduced computational effort, achieving a 20 times reduction in computational time while receiving similar results. In this work, we focus on carbon-doped titanate nanotubes for hydrogen applications, but the method is adaptable for other nanocomposite applications. The findings provide a universal framework for the investigation of nanotube-based materials.
format Preprint
id arxiv_https___arxiv_org_abs_2501_17087
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Multiscale simulations of three-dimensional nanotube networks: Enhanced modeling using unit cells
Gumpert, Fabian
Eitel, Dominik
Kottas, Olaf
Helbig, Uta
Lohbreier, Jan
Computational Physics
Materials Science
Applied Physics
This study presents a simulation approach for three-dimensional nanotube networks using cubic and tetragonal unit cells to enhance modeling efficiency. A random-walk algorithm was developed to generate these networks, which were analyzed in a Finite Element Method (FEM) simulation to assess their electrical conductivity. The percolation probability as a function of the nanotube filling factor can be derived from these simulation results. It is found that smaller tetragonal unit cells can replicate the behavior of larger networks with significantly reduced computational effort, achieving a 20 times reduction in computational time while receiving similar results. In this work, we focus on carbon-doped titanate nanotubes for hydrogen applications, but the method is adaptable for other nanocomposite applications. The findings provide a universal framework for the investigation of nanotube-based materials.
title Multiscale simulations of three-dimensional nanotube networks: Enhanced modeling using unit cells
topic Computational Physics
Materials Science
Applied Physics
url https://arxiv.org/abs/2501.17087