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Coexistence of large-area topological pseudospin and valley states in a tri-band heterostructure system

Sijie Li, Menglin L. N. Chen, Zhihao Lan, Li Ping

2023Optics Letters24 citationsDOI

Abstract

The rapid development of topological photonics has significantly revolutionized our comprehension of electromagnetic wave manipulation in recent decades. Recent research exploiting large-area topological states inserts an additional gapless PC structure between topologically trivial and nontrivial PCs, effectively introducing the mode width degree of freedom. Nevertheless, these heterostructures mainly support only single-type waveguide states operating within a single frequency band. To address these limitations, we propose a novel, to the best of our knowledge, tri-band three-layer heterostructure system, supporting both large-area pseudospin- and valley-locked states. The system showcases tunable mode widths with different operational bandwidths. Moreover, the heterostructures exhibit inherent topological characteristics and reflection-free interfacing, which are verified in the well-designed Z-shaped channels. The proposed heterostructure system can be used to design multi-band multi-functional high-flexibility topological devices, providing great advantages for enlarging the on-chip integrated communication systems.

Topics & Concepts

HeterojunctionInterfacingGapless playbackTopology (electrical circuits)PhotonicsRealization (probability)PhysicsPhotonic crystalFlexibility (engineering)Computer scienceOpticsOptoelectronicsEngineeringElectrical engineeringMathematicsCondensed matter physicsStatisticsComputer hardwareTopological Materials and PhenomenaPhotonic and Optical DevicesMetamaterials and Metasurfaces Applications
Coexistence of large-area topological pseudospin and valley states in a tri-band heterostructure system | Litcius