Litcius/Paper detail

Knots are not for naught: Design, properties, and topology of hierarchical intertwined microarchitected materials

Widianto P. Moestopo, Sammy Shaker, Weiting Deng, Julia R. Greer

2023Science Advances41 citationsDOIOpen Access PDF

Abstract

Lightweight and tough engineered materials are often designed with three-dimensional hierarchy and interconnected structural members whose junctions are detrimental to their performance because they serve as stress concentrations for damage accumulation and lower mechanical resilience. We introduce a previously unexplored class of architected materials, whose components are interwoven and contain no junctions, and incorporate micro-knots as building blocks within these hierarchical networks. Tensile experiments, which show close quantitative agreements with an analytical model for overhand knots, reveal that knot topology allows a new regime of deformation capable of shape retention, leading to a ~92% increase in absorbed energy and an up to ~107% increase in failure strain compared to woven structures, along with an up to ~11% increase in specific energy density compared to topologically similar monolithic lattices. Our exploration unlocks knotting and frictional contact to create highly extensible low-density materials with tunable shape reconfiguration and energy absorption capabilities.

Topics & Concepts

Knot (papermaking)HierarchyTopology (electrical circuits)ExtensibilityResilience (materials science)Control reconfigurationUltimate tensile strengthComputer scienceScalabilityMaterials scienceNanotechnologyStructural engineeringComposite materialMathematicsEngineeringDatabaseOperating systemMarket economyEconomicsEmbedded systemCombinatoricsAdvanced Materials and MechanicsCellular and Composite StructuresAdhesion, Friction, and Surface Interactions