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Plate-nanolattices at the theoretical limit of stiffness and strength

Cameron Crook, J. Bauer, Anna Güell Izard, Cristine Santos de Oliveira, Juliana Martins de Souza e Silva, Jonathan B. Berger, Lorenzo Valdevit

2020Nature Communications277 citationsDOIOpen Access PDF

Abstract

Though beam-based lattices have dominated mechanical metamaterials for the past two decades, low structural efficiency limits their performance to fractions of the Hashin-Shtrikman and Suquet upper bounds, i.e. the theoretical stiffness and strength limits of any isotropic cellular topology, respectively. While plate-based designs are predicted to reach the upper bounds, experimental verification has remained elusive due to significant manufacturing challenges. Here, we present a new class of nanolattices, constructed from closed-cell plate-architectures. Carbon plate-nanolattices are fabricated via two-photon lithography and pyrolysis and shown to reach the Hashin-Shtrikman and Suquet upper bounds, via in situ mechanical compression, nano-computed tomography and micro-Raman spectroscopy. Demonstrating specific strengths surpassing those of bulk diamond and average performance improvements up to 639% over the best beam-nanolattices, this study provides detailed experimental evidence of plate architectures as a superior mechanical metamaterial topology.

Topics & Concepts

MetamaterialIsotropyDiamondStiffnessTopology (electrical circuits)Topology optimizationLimit (mathematics)Materials scienceUpper and lower boundsBeam (structure)Composite materialPhysicsStructural engineeringOpticsOptoelectronicsMathematicsFinite element methodMathematical analysisElectrical engineeringEngineeringForce Microscopy Techniques and ApplicationsCellular and Composite StructuresDiamond and Carbon-based Materials Research
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