Fracton-elasticity duality of two-dimensional superfluid vortex crystals: defect interactions and quantum melting
Dung Nguyen, Andrey Gromov, Sergej Moroz
Abstract
Employing the fracton-elastic duality, we develop a low-energy effective theory of a zero-temperature vortex crystal in a two-dimensional bosonic superfluid which naturally incorporates crystalline topological defects. We extract static interactions between these defects and investigate several continuous quantum transitions triggered by the Higgs condensation of vortex vacancies/interstitials and dislocations. We propose that the quantum melting of the vortex crystal towards the hexatic or smectic phase may occur via a pair of continuous transitions separated by an intermediate vortex supersolid phase.
Topics & Concepts
SupersolidVortexSuperfluidityPhysicsCondensed matter physicsTopological defectPhase transitionCrystal (programming language)Duality (order theory)Quantum vortexPhase (matter)QuantumCondensationSuperfluid filmQuantum mechanicsQuantum phasesWigner crystalHiggs bosonQuantum fluidPercolation (cognitive psychology)Quantum fluctuationMelting temperatureBosonBose–Einstein condensateQuantum phase transitionQuantum dotClassical mechanicsVortex stateSuperconductivityQuantum many-body systemsTopological Materials and PhenomenaQuantum, superfluid, helium dynamics