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Selective and tunable excitation of topological non-Hermitian quasi-edge modes

Stefano Longhi

2022Proceedings of the Royal Society A Mathematical Physical and Engineering Sciences10 citationsDOIOpen Access PDF

Abstract

Non-Hermitian lattices under semi-infinite boundary conditions sustain an extensive number of exponentially localized states, dubbed non-Hermitian quasi-edge modes. Quasi-edge states arise rather generally in systems displaying the non-Hermitian skin effect and can be predicted from the non-trivial topology of the energy spectrum under periodic boundary conditions via a bulk-edge correspondence. However, the selective excitation of the system in one among the infinitely many topological quasi-edge states is challenging both from practical and conceptual viewpoints. In fact, in any realistic system with a finite lattice size most of the quasi-edge states collapse and become metastable states. Here we suggest a route toward the selective and tunable excitation of topological quasi-edge states that avoids the collapse problem by emulating semi-infinite lattice boundaries via tailored on-site potentials at the edges of a finite lattice. We illustrate such a strategy by considering a non-Hermitian topological interface obtained by connecting two Hatano–Nelson chains with opposite imaginary gauge fields, which is amenable for a full analytical treatment.

Topics & Concepts

Hermitian matrixPhysicsLattice (music)MetastabilityExcitationTopology (electrical circuits)Boundary (topology)Boundary value problemQuantum mechanicsMathematicsMathematical analysisCombinatoricsAcousticsQuantum Mechanics and Non-Hermitian PhysicsTopological Materials and PhenomenaQuantum chaos and dynamical systems
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