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Main Authors: Sarate, Palash, Bhat, Mohd. Ilyas, Murthy, Tejas G., Sharma, Prerna
Format: Preprint
Published: 2026
Subjects:
Online Access:https://arxiv.org/abs/2602.09588
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author Sarate, Palash
Bhat, Mohd. Ilyas
Murthy, Tejas G.
Sharma, Prerna
author_facet Sarate, Palash
Bhat, Mohd. Ilyas
Murthy, Tejas G.
Sharma, Prerna
contents Entangled granular systems exhibit mechanical rigidity and resistance to deformation, reminiscent of cohesive materials, due to their reduced degrees of freedom and contact friction. A quantitative understanding of how classical granular phenomena, such as shear localization and plastic flow, appear in such geometrically cohesive systems remains unknown. Here, we investigate this using granular chain ensembles subjected to direct shear tests. Our experiments reveal that chains longer than four beads exhibit pronounced shear hardening, which is nearly independent of the applied normal stress and is accompanied by the complete suppression of shear localization. The volume dilation of the long chain ensembles also does not vanish in the steady state. We complement this phenomenology, which is distinct from that of typical frictional granular ensembles, with DEM simulations. The simulations reveal that tensile forces are generated due to particles being locally jammed, characterized by a high non-covalent coordination number. Consequently, this leads to a deformation that shows a very diffuse region of localization and enhanced shear hardening. Overall, our study highlights that granular chains provide a systematic route to map how connectivity constraints impact flow properties and mechanical rigidity.
format Preprint
id arxiv_https___arxiv_org_abs_2602_09588
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Topological constraints suppress shear localization in granular chain ensembles
Sarate, Palash
Bhat, Mohd. Ilyas
Murthy, Tejas G.
Sharma, Prerna
Soft Condensed Matter
Entangled granular systems exhibit mechanical rigidity and resistance to deformation, reminiscent of cohesive materials, due to their reduced degrees of freedom and contact friction. A quantitative understanding of how classical granular phenomena, such as shear localization and plastic flow, appear in such geometrically cohesive systems remains unknown. Here, we investigate this using granular chain ensembles subjected to direct shear tests. Our experiments reveal that chains longer than four beads exhibit pronounced shear hardening, which is nearly independent of the applied normal stress and is accompanied by the complete suppression of shear localization. The volume dilation of the long chain ensembles also does not vanish in the steady state. We complement this phenomenology, which is distinct from that of typical frictional granular ensembles, with DEM simulations. The simulations reveal that tensile forces are generated due to particles being locally jammed, characterized by a high non-covalent coordination number. Consequently, this leads to a deformation that shows a very diffuse region of localization and enhanced shear hardening. Overall, our study highlights that granular chains provide a systematic route to map how connectivity constraints impact flow properties and mechanical rigidity.
title Topological constraints suppress shear localization in granular chain ensembles
topic Soft Condensed Matter
url https://arxiv.org/abs/2602.09588