Density-wave geometric perturbation in a single-layer photonic graphene slab engineers radiative flat bands, anisotropic dispersion, band inversion, and Jackiw-Rebbi interface states.
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3 Pith papers cite this work. Polarity classification is still indexing.
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2026 3verdicts
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Periodic electrostatic potentials in TMDs induce up to 10 meV optical valley splitting and linear dispersion in the lowest exciton band, potentially enabling 2D exciton Bose condensation and superfluidity.
A symmetry-adapted quasi-band method computes Landau levels and magneto-optical conductivity in 30° quasi-periodic twisted bilayer graphene, classifying levels by Landau index and angular momentum while revealing weak field dependence in flat bands.
citing papers explorer
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Geometric Engineering of Flat Bands in a Single-layer Photonic Graphene
Density-wave geometric perturbation in a single-layer photonic graphene slab engineers radiative flat bands, anisotropic dispersion, band inversion, and Jackiw-Rebbi interface states.
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Transition Metal Dichalcogenide Excitons in Periodic Electrostatic Potentials: Center-of-Mass Models
Periodic electrostatic potentials in TMDs induce up to 10 meV optical valley splitting and linear dispersion in the lowest exciton band, potentially enabling 2D exciton Bose condensation and superfluidity.
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Landau levels and magneto-optics in 30$^\circ$ quasi-periodic twisted bilayer graphene
A symmetry-adapted quasi-band method computes Landau levels and magneto-optical conductivity in 30° quasi-periodic twisted bilayer graphene, classifying levels by Landau index and angular momentum while revealing weak field dependence in flat bands.