Litcius/Paper detail

Topological phases of quantized light

Han Cai, Da-Wei Wang

2020National Science Review47 citationsDOIOpen Access PDF

Abstract

Abstract Topological photonics is an emerging research area that focuses on the topological states of classical light. Here we reveal the topological phases that are intrinsic to the quantum nature of light, i.e. solely related to the quantized Fock states and the inhomogeneous coupling strengths between them. The Hamiltonian of two cavities coupled with a two-level atom is an intrinsic one-dimensional Su-Schriefer-Heeger model of Fock states. By adding another cavity, the Fock-state lattice is extended to two dimensions with a honeycomb structure, where the strain due to the inhomogeneous coupling strengths of the annihilation operator induces a Lifshitz topological phase transition between a semimetal and three band insulators within the lattice. In the semimetallic phase, the strain is equivalent to a pseudomagnetic field, which results in the quantization of the Landau levels and the valley Hall effect. We further construct an inhomogeneous Fock-state Haldane model where the topological phases can be characterized by the topological markers. With d cavities being coupled to the atom, the lattice is extended to d − 1 dimensions without an upper limit. In this study we demonstrate a fundamental distinction between the topological phases in quantum and classical optics and provide a novel platform for studying topological physics in dimensions higher than three.

Topics & Concepts

PhysicsTopological insulatorTopological degeneracyTopological orderTopology (electrical circuits)Hamiltonian (control theory)Symmetry protected topological orderLattice (music)Topological entropy in physicsQuantization (signal processing)Quantum mechanicsQuantum Hall effectPhotonicsCoupling (piping)QuantumAnnihilationQuantum phasesToric codeGeometric phaseFock spaceQuantum phase transitionCondensed matter physicsOperator (biology)Phase transitionPhase (matter)Quantum opticsLandau quantizationTheoretical physicsElectronic band structureQuantum anomalous Hall effectTopological defectUltracold atomTopological quantum numberTopological Materials and PhenomenaChemical and Physical Properties of MaterialsGraphene research and applications