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Paper detail

Bimorphic Floquet Topological Insulators

Topological theories have established a new set of rules that govern the transport properties in a wide variety of wave-mechanical settings. In a marked departure from the established approaches that induce Floquet topological phases by specifically tailored discrete coupling protocols or helical lattice motions, we introduce a new class of bimorphic Floquet topological insulators that leverage connective chains with periodically modulated on-site potentials to unlock new topological features in the system. In exploring a 'chain-driven' generalization of the archetypical Floquet honeycomb lattice, we identify a rich phase structure that can host multiple non-trivial topological phases associated simultaneously with both Chern-type and anomalous chiral states. Experiments carried out in photonic waveguide lattices reveal a unique and strongly confined helical edge state that, owing to its origin in bulk flat bands, can be set into motion in a topologically protected fashion, or halted at will, without compromising its adherence to individual lattice sites.

preprint2022arXivOpen access
Georgios G. PyrialakosJulius BeckMatthias HeinrichLukas J. MaczewskyNikolaos V. KantartzisMercedeh KhajavikhanAlexander SzameitDemetrios N. Christodoulides
physics.optics
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Authors

Georgios G. PyrialakosJulius BeckMatthias HeinrichLukas J. MaczewskyNikolaos V. KantartzisMercedeh KhajavikhanAlexander SzameitDemetrios N. Christodoulides

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