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Conformal elasticity of mechanism-based metamaterials

Michael Czajkowski, Corentin Coulais, Martin van Hecke, D. Zeb Rocklin

2022Nature Communications68 citationsDOIOpen Access PDF

Abstract

Deformations of conventional solids are described via elasticity, a classical field theory whose form is constrained by translational and rotational symmetries. However, flexible metamaterials often contain an additional approximate symmetry due to the presence of a designer soft strain pathway. Here we show that low energy deformations of designer dilational metamaterials will be governed by a scalar field theory, conformal elasticity, in which the nonuniform, nonlinear deformations observed under generic loads correspond with the well-studied-conformal-maps. We validate this approach using experiments and finite element simulations and further show that such systems obey a holographic bulk-boundary principle, which enables an analytic method to predict and control nonuniform, nonlinear deformations. This work both presents a unique method of precise deformation control and demonstrates a general principle in which mechanisms can generate special classes of soft deformations.

Topics & Concepts

MetamaterialConformal mapPhysicsNonlinear systemElasticity (physics)Scalar fieldClassical mechanicsScalar (mathematics)Rotational symmetryTranslational symmetrySymmetry (geometry)Finite element methodHolographyDeformation (meteorology)Field (mathematics)Elastic energyTopology (electrical circuits)Theoretical physicsWork (physics)Scalar potentialLinear elasticityMathematical analysisConformal symmetryTransformation opticsTopological defectAdvanced Materials and MechanicsCellular and Composite StructuresNonlocal and gradient elasticity in micro/nano structures
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