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Textile Hinges Enable Extreme Properties of Kirigami Metamaterials

Anne S. Meeussen, Giovanni Bordiga, Audrey X. Chang, Ben Spoettling, Kaitlyn P. Becker, L. Mahadevan, Katia Bertoldi

2024Advanced Functional Materials13 citationsDOIOpen Access PDF

Abstract

Abstract Mechanical metamaterials—structures with unusual properties that emerge from their internal architecture—that are designed to undergo large deformations typically exploit large internal rotations, and therefore, necessitate the incorporation of flexible hinges. Kirigami structures, made by introducing ordered cuts in a planar material, are one such example. In the mechanism limit, these structures consist of rigid bodies connected by ideal hinges that deform at zero energy cost. However, fabrication in this limit has remained elusive. Here, we demonstrate that the integration of textile hinges provides a scalable platform for creating large kirigami metamaterials with mechanism‐like behaviors. Further, leveraging recently introduced kinematic optimization tools, we show that textile hinges enable extreme shape‐morphing responses, paving the way for the next generation of mechanism‐based metamaterials.

Topics & Concepts

HingeMetamaterialMorphingMechanism (biology)PlanarCompliant mechanismMaterials scienceLimit (mathematics)FabricationScalabilityKinematicsTextileComputer scienceExploitStructural engineeringMechanical engineeringAerospace engineeringFinite element methodEngineeringPhysicsComposite materialClassical mechanicsOptoelectronicsComputer graphics (images)Computer securityMathematicsPathologyQuantum mechanicsMathematical analysisComputer visionMedicineDatabaseAlternative medicineAdvanced Materials and MechanicsCellular and Composite StructuresStructural Analysis and Optimization
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