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Controlling topological phases of matter with quantum light

Olesia Dmytruk, Marco Schirò

2022Communications Physics53 citationsDOIOpen Access PDF

Abstract

Abstract Controlling the topological properties of quantum matter is a major goal of condensed matter physics. A major effort in this direction has been devoted to using classical light in the form of Floquet drives to manipulate and induce states with non-trivial topology. A different route can be achieved with cavity photons. Here we consider a prototypical model for topological phase transition, the one-dimensional Su-Schrieffer-Heeger model, coupled to a single mode cavity. We show that quantum light can affect the topological properties of the system, including the finite-length energy spectrum hosting edge modes and the topological phase diagram. In particular we show that depending on the lattice geometry and the strength of light-matter coupling one can either turn a trivial phase into a topological one or viceversa using quantum cavity fields. Furthermore, we compute the polariton spectrum of the coupled electron-photon system, and we note that the lower polariton branch disappears at the topological transition point. This phenomenon can be used to probe the phase transition in the Su-Schrieffer-Heeger model.

Topics & Concepts

PhysicsTopological orderFloquet theoryTopology (electrical circuits)Topological degeneracyPolaritonQuantum phase transitionQuantum phasesPhotonQuantumTopological quantum numberPhase transitionLattice (music)Coupling (piping)Quantum mechanicsSymmetry protected topological orderCondensed matter physicsMechanical engineeringAcousticsCombinatoricsNonlinear systemEngineeringMathematicsTopological Materials and PhenomenaStrong Light-Matter InteractionsMechanical and Optical Resonators