Rigidity Criteria for Chainmail Consisting of Tessellations of Torus Knots
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1.
California Institute of Technology
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2.
Nanyang Technological University
Abstract
Interlocked and polycatenated material systems, consisting of discrete, nonconvex particles linked to their nearest neighbors, such as chainmail fabrics, have been shown to undergo a jamming transition that increases their rigidity under boundary compression. This rigidity transition is associated with an increase in contact number between particles. In architected materials, rigidity is described by theories such as the Maxwell criterion. In this Letter, we propose a rigidity theory for a type of interlocked material system: the torus knot tessellation. Torus knot tessellations are structured fabrics composed of particles shaped as torus knots. In these fabrics, we theoretically demonstrate that in-plane rigidity is governed by a modified Maxwell criterion, while out-of-plane rigidity is governed by a crease line criterion. These theories provide a framework for the design of rigidity of these fabrics.
Copyright and License
© 2025 American Physical Society.
Acknowledgement
This research has been supported by the National Science Foundation (Grant No. 2242925) and the Multi University Research Initiative (Grant No. MURI ARO W911NF-22-2-0109). We thank Prof. José E. Andrade’s group for their initial implementation of the LSDEM simulation.
Supplemental Material
The supplementary material provides additional information regarding methods, theoretical derivations, numerical models, results and analysis performed to obtain the results described in the main paper.
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Additional details
- National Science Foundation
- DMR-2242925
- Office of Naval Research
- ARO W911NF-22-2-0109
- Accepted
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2025-06-18
- Caltech groups
- Division of Engineering and Applied Science (EAS)
- Publication Status
- Published