Tunable entanglement and strength in "granular metamaterials" based on staple-like particles: Experiments and discrete element models

TL;DR

This study investigates the tensile properties and mechanics of staple-like particle bundles, revealing an optimal angle for maximum strength and demonstrating dynamic force chain behavior, positioning entangled matter as tunable granular metamaterials.

Contribution

It introduces experimental and modeling insights into how staple shape influences entanglement strength and dynamics, highlighting the potential of these materials as reconfigurable and tunable metamaterials.

Findings

Optimal crown-leg angle maximizes tensile strength.

Force transmission occurs through 1-3 dynamic force chains.

Entangled materials exhibit combined strength, toughness, and reconfigurability.

Abstract

Entangled matter displays unusual and attractive properties and mechanisms: tensile strength, capabilities for assembly and disassembly, damage tolerance. While some of the attributes and mechanisms share some traits with traditional granular materials, fewer studies have focused on entanglement and strength and there are large gaps in our understanding of the mechanics of these materials. In this report we focus on the tensile properties and mechanics of bundles made of staple-like particles, and particularly on the effect of adjusting the angle between the legs and the crown in individual staples. Our experiments, combined with discrete element models, show competing mechanisms between entanglement strength and geometric engagement between particles, giving rise to an optimum crown-leg angle that maximizes strength. We also show that tensile forces are transmitted by a small fraction of the staples, which is organized in only 1-3 force chains. The formation and breakage of these chains is highly dynamic: as force chains break, they are replaced by fresh ones which were previously mechanically invisible. Entangled matter as "granular metamaterials" offer interesting perspectives in terms of materials design, and a vast design space for individual particles. Since their properties can be tuned with the shape of the staple, we interpret these entangled materials are "granular metamaterials" with unusual combination of properties: simultaneous strength and toughness, controlled assembly and disassembly, re-conformability, recyclability.