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| Autores principales: | , |
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| Formato: | Preprint |
| Publicado: |
2025
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| Materias: | |
| Acceso en línea: | https://arxiv.org/abs/2510.09933 |
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| _version_ | 1866911203757916160 |
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| author | Pezeshki, Saeed Barthelat, Francois |
| author_facet | Pezeshki, Saeed Barthelat, Francois |
| contents | Entangled materials offer attractive structural features including tensile strength and large deformations, combined with infinite assembly and disassembly capabilities. How the geometry of individual particles governs entanglement, and in turn translates into macroscopic structural properties, provides a rich landscape in terms of mechanics and offers intriguing possibilities in terms of structural design. Despite this potential, there are major knowledge gaps on the entanglement mechanisms and how they can generate strength. In particular, vibrations are known to have strong effects on entanglement and disentanglement but the exact mechanisms underlying these observations are unknown. In this report we present tensile tests and discrete element method (DEM) simulations on bundles of entangled staple-like particles that capture the combined effects of particle geometry and vibrations on local entanglement, tensile force chains and strength. We show that standard steel staples with $θ= 90^\circ$ crown-leg angle initially entangle better than $θ= 20^\circ$ modified staples because of their more "open" geometry. However, as vibrations are applied entanglement increase faster in $θ= 20^\circ$ bundles, so that they develop strong and stable tensile force chains, producing bundles which are almost ten times stronger than $θ= 90^\circ$ bundles. Both tensile strength and entanglement density increase with vibrations and also with deformations, up to a steady state value. At that point the rate of entanglement equals the rate of disentanglement, and each of these rates remains relatively high. Finally, we show that vibration can be used as a manipulation strategy to either entangle or disentangle staple-like entangled granular materials, with confinement playing a significant role in determining whether vibration promotes entanglement or disentanglement. |
| format | Preprint |
| id |
arxiv_https___arxiv_org_abs_2510_09933 |
| institution | arXiv |
| publishDate | 2025 |
| record_format | arxiv |
| spellingShingle | Combined effects of particle geometry and applied vibrations on the mechanics and strength of entangled materials Pezeshki, Saeed Barthelat, Francois Soft Condensed Matter Entangled materials offer attractive structural features including tensile strength and large deformations, combined with infinite assembly and disassembly capabilities. How the geometry of individual particles governs entanglement, and in turn translates into macroscopic structural properties, provides a rich landscape in terms of mechanics and offers intriguing possibilities in terms of structural design. Despite this potential, there are major knowledge gaps on the entanglement mechanisms and how they can generate strength. In particular, vibrations are known to have strong effects on entanglement and disentanglement but the exact mechanisms underlying these observations are unknown. In this report we present tensile tests and discrete element method (DEM) simulations on bundles of entangled staple-like particles that capture the combined effects of particle geometry and vibrations on local entanglement, tensile force chains and strength. We show that standard steel staples with $θ= 90^\circ$ crown-leg angle initially entangle better than $θ= 20^\circ$ modified staples because of their more "open" geometry. However, as vibrations are applied entanglement increase faster in $θ= 20^\circ$ bundles, so that they develop strong and stable tensile force chains, producing bundles which are almost ten times stronger than $θ= 90^\circ$ bundles. Both tensile strength and entanglement density increase with vibrations and also with deformations, up to a steady state value. At that point the rate of entanglement equals the rate of disentanglement, and each of these rates remains relatively high. Finally, we show that vibration can be used as a manipulation strategy to either entangle or disentangle staple-like entangled granular materials, with confinement playing a significant role in determining whether vibration promotes entanglement or disentanglement. |
| title | Combined effects of particle geometry and applied vibrations on the mechanics and strength of entangled materials |
| topic | Soft Condensed Matter |
| url | https://arxiv.org/abs/2510.09933 |