Polarization-sensitive resonant absorber based on splitted tamm plasmon polariton

“…8–10 Therefore, 1-D PhCs have received much attention in the past three decades. 11–23 Assisted by their photonic bandgaps (PBGs), 1-D PhCs have been widely exploited to design absorbers, 24–28 emitters, 29,30 solar cells, 31,32 photodetectors, 33,34 sensors, 35–37 and filters. 38 The typical 1-D PhCs are all-dielectric 1-D PhCs entirely composed of isotropic dielectrics.…”

A redshifted photonic bandgap and wide-angle polarization selection in an all-hyperbolic-metamaterial one-dimensional photonic crystal

“…8–10 Therefore, 1-D PhCs have received much attention in the past three decades. 11–23 Assisted by their photonic bandgaps (PBGs), 1-D PhCs have been widely exploited to design absorbers, 24–28 emitters, 29,30 solar cells, 31,32 photodetectors, 33,34 sensors, 35–37 and filters. 38 The typical 1-D PhCs are all-dielectric 1-D PhCs entirely composed of isotropic dielectrics.…”

A redshifted photonic bandgap and wide-angle polarization selection in an all-hyperbolic-metamaterial one-dimensional photonic crystal

“…1–3 Unlike a surface plasmon polariton, TPP can be excited by optical radiation of any polarization without phase matching. 4 Various nanophotonic devices such as lasers, 5 optical switches, 6–8 ideal absorbers, 9–11 thermal emitters, 12 single photon sources, 13 photodetectors, 14–17 and sensors 18–21 were proposed on the basis of the TPP. The TPP can be coupled with other types of modes, with their simultaneous excitation in the system.…”

Hybrid Tamm and quasi-BIC microcavity modes

Lithography-free polarization-dependent absorber based on α-MoO3