Narrow band filter designed from Bravais-Moiré two-dimensional photonic crystal

This work investigates the light propagation through a narrow-band filter based on a two-dimensional photonic crystal with Bravais-Moiré lattice and dielectric elements of circular cross section. We report on the corresponding gap mapping as a function of the radius of dielectric cores as well as th...

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Bibliographic Details
Published in:Photonics and nanostructures 2022-12, Vol.52, p.101082, Article 101082
Main Authors: Bareño-Silva, J., Caro-Lopera, F.J., Gómez-Urrea, H.A., Mora-Ramos, M.E.
Format: Article
Language:English
Subjects:
2D photonic crystal
Biosensing
Bravais-Moiré lattice
Microcavity
Narrowband filter
Photonic waveguide
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Summary:This work investigates the light propagation through a narrow-band filter based on a two-dimensional photonic crystal with Bravais-Moiré lattice and dielectric elements of circular cross section. We report on the corresponding gap mapping as a function of the radius of dielectric cores as well as the dispersion relations of TM modes for a sample 2D structure and for the waveguide system built of defect lines within such crystal, coupled to a microcavity. The proposed design is tested via numerical simulations, using the finite element method, aiming at its eventual biosensing performance. Cavity resonant frequencies were determined for different biological molecules, finding values of quality factor up to Q = 54,858.1. A linear response against changes in the index of refraction of different analyzed substances was found for the filter. Sensibility of up to 13086 nm/RIU (equivalent to 73.3 GHz/RIU), and figure of merit up to 3112.32 RIU−1 were determined. This points at the possible use of this kind of filters for developing THz-range biosensors with label-free medical and biological applications. •Bravais-Moiré two-dimensional photonic crystals.•Photonic band gap mapping, dispersion relations and transmittance.•Photonic crystal cavity simulations and filtering analysis.•Molecule sensing, high quality factors and figures of merit.
ISSN:1569-4410
1569-4429
DOI:10.1016/j.photonics.2022.101082