Litcius/Paper detail

Exceptional non-Hermitian topological edge mode and its application to active matter

Kazuki Sone, Yuto Ashida, Takahiro Sagawa

2020Nature Communications60 citationsDOIOpen Access PDF

Abstract

Topological materials exhibit edge-localized scattering-free modes protected by their nontrivial bulk topology through the bulk-edge correspondence in Hermitian systems. While topological phenomena have recently been much investigated in non-Hermitian systems with dissipations and injections, the fundamental principle of their edge modes has not fully been established. Here, we reveal that, in non-Hermitian systems, robust gapless edge modes can ubiquitously appear owing to a mechanism that is distinct from bulk topology, thus indicating the breakdown of the bulk-edge correspondence. The robustness of these edge modes originates from yet another topological structure accompanying the branchpoint singularity around an exceptional point, at which eigenvectors coalesce and the Hamiltonian becomes nondiagonalizable. Their characteristic complex eigenenergy spectra are applicable to realize lasing wave packets that propagate along the edge of the sample. We numerically confirm the emergence and the robustness of the proposed edge modes in the prototypical lattice models. Furthermore, we show that these edge modes appear in a model of chiral active matter based on the hydrodynamic description, demonstrating that active matter can exhibit an inherently non-Hermitian topological feature. The proposed general mechanism would serve as an alternative designing principle to realize scattering-free edge current in non-Hermitian devices, going beyond the existing frameworks of non-Hermitian topological phases.

Topics & Concepts

PhysicsGapless playbackTopology (electrical circuits)Hamiltonian (control theory)SingularityLattice (music)Robustness (evolution)Eigenvalues and eigenvectorsActive matterTopological insulatorAsymmetryHermitian matrixEnhanced Data Rates for GSM EvolutionTopological defectTopological orderQuantum mechanicsTheoretical physicsNormal modeSpectral lineFormalism (music)Topological degeneracyQuantum Mechanics and Non-Hermitian PhysicsTopological Materials and PhenomenaNonlinear Photonic Systems