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Topological Defects in Solids with Odd Elasticity

Lara Braverman, Colin Scheibner, Bryan VanSaders, Vincenzo Vitelli

2021Physical Review Letters58 citationsDOIOpen Access PDF

Abstract

Crystallography typically studies collections of point particles whose interaction forces are the gradient of a potential. Lifting this assumption generically gives rise in the continuum limit to a form of elasticity with additional moduli known as odd elasticity. We show that such odd elastic moduli modify the strain induced by topological defects and their interactions, even reversing the stability of, otherwise, bound dislocation pairs. Beyond continuum theory, isolated dislocations can self propel via microscopic work cycles active at their cores that compete with conventional Peach-Koehler forces caused, for example, by an ambient torque density. We perform molecular dynamics simulations isolating active plastic processes and discuss their experimental relevance to solids composed of spinning particles, vortexlike objects, and robotic metamaterials.

Topics & Concepts

ModuliElasticity (physics)Topological defectPhysicsSpinningClassical mechanicsDislocationTopology (electrical circuits)Work (physics)TorqueCrystallographic defectTopological quantum numberContinuum hypothesisReversingCondensed matter physicsStability (learning theory)Elastic modulusMolecular dynamicsPlanarMaterials scienceLinear elasticityTheoretical physicsLimit (mathematics)Structural stabilityPlasticityPoint (geometry)Formalism (music)Nonlocal and gradient elasticity in micro/nano structuresAdvanced Materials and MechanicsForce Microscopy Techniques and Applications
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