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Main Authors: Reyes-Martinez, Marcos A., Kadar, Alain, Dunne, Steven, Glotzer, Sharon C., Soles, Christopher L., Kotov, Nicholas A.
Format: Preprint
Published: 2024
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Online Access:https://arxiv.org/abs/2412.15344
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author Reyes-Martinez, Marcos A.
Kadar, Alain
Dunne, Steven
Glotzer, Sharon C.
Soles, Christopher L.
Kotov, Nicholas A.
author_facet Reyes-Martinez, Marcos A.
Kadar, Alain
Dunne, Steven
Glotzer, Sharon C.
Soles, Christopher L.
Kotov, Nicholas A.
contents Interconnected networks of rigid struts are critical for application in lightweight, load-bearing structures. However, accurately modeling stress distribution in these strut lattices poses significant computational challenges due to its strong dependence on organizational patterns, boundary conditions, and collective effects. Leveraging two-dimensional strut lattices that enable visualization of local elastic deformation, we investigate how graph theory (GT) provides a framework for stress prediction. We investigate how the geometric features often neglected by GT play a crucial role in the behavior of anisotropic networks. We also address the challenge of topological continuity that arises when applying discrete mathematics to physical structures. We show that modified centrality parameters combining lattice topology with geometry more accurately predict local stress, as validated through birefringence imaging and finite element modeling. Finally, we show how further improvements are made by incorporating strut lattice boundary conditions into the centrality definition, in a manner that simultaneously simplifies the computational cost.
format Preprint
id arxiv_https___arxiv_org_abs_2412_15344
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Graph-Theoretical Description and Continuity Problems for Stress Propagation Through Complex Strut Lattices
Reyes-Martinez, Marcos A.
Kadar, Alain
Dunne, Steven
Glotzer, Sharon C.
Soles, Christopher L.
Kotov, Nicholas A.
Materials Science
Interconnected networks of rigid struts are critical for application in lightweight, load-bearing structures. However, accurately modeling stress distribution in these strut lattices poses significant computational challenges due to its strong dependence on organizational patterns, boundary conditions, and collective effects. Leveraging two-dimensional strut lattices that enable visualization of local elastic deformation, we investigate how graph theory (GT) provides a framework for stress prediction. We investigate how the geometric features often neglected by GT play a crucial role in the behavior of anisotropic networks. We also address the challenge of topological continuity that arises when applying discrete mathematics to physical structures. We show that modified centrality parameters combining lattice topology with geometry more accurately predict local stress, as validated through birefringence imaging and finite element modeling. Finally, we show how further improvements are made by incorporating strut lattice boundary conditions into the centrality definition, in a manner that simultaneously simplifies the computational cost.
title Graph-Theoretical Description and Continuity Problems for Stress Propagation Through Complex Strut Lattices
topic Materials Science
url https://arxiv.org/abs/2412.15344