Resonance behavior of diffraction on encapsulated guided-mode grating of subwavelength thickness

We study the resonances in transmission of a subwavelength dielectric lossless structure, periodic in one direction and infinite in the orthogonal (i.e. the effectively 2D problem). We are interested in the case of an encapsulated grid, deeply embedded into an optically-homogeneous surrounding mediu...

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Published inPhotonics and nanostructures Vol. 46; p. 100953
Main Authors Efremova, E.A., Perminov, S.V., Vergeles, S.S.
Format Journal Article
LanguageEnglish
Published Amsterdam Elsevier B.V 01.09.2021
Elsevier Science Ltd
Subjects
Amplitudes
Coupling
Diffraction grating
Encapsulation
Incidence angle
Linear functions
Mode coupling
Periodic structures
Reflectance
Refractivity
Resonance
Resonance waveguide grating
Subwavelength dielectric structure
Waveguides
Diffraction grating
Resonance waveguide grating
Mode coupling
Subwavelength dielectric structure
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Abstract We study the resonances in transmission of a subwavelength dielectric lossless structure, periodic in one direction and infinite in the orthogonal (i.e. the effectively 2D problem). We are interested in the case of an encapsulated grid, deeply embedded into an optically-homogeneous surrounding medium. In the case, even a thin periodic structure, characterized by a positive relative excess of the refractive index, demonstrates full reflectance in a narrow bandwidth due to its waveguide capability. Here we systematically study all existing types of the diffraction spectra of the grids. We show that the diffraction type of the grid is determined by the geometric filling factor and the degree of asymmetry of the grid’s cross section profile. These two parameters are some linear functions of the complex amplitude of the second spatial Fourier harmonic of the material distribution in the grid. The amplitude determines the coupling between two resonant guiding modes. The coupling is relevant for relatively small angles of incidence, for which it substantially modifies the diffraction spectra in the vicinity of the resonances. Also, we revealed a particular type of diffraction grids, which show suppressed resonances at a relatively large angle of incidence but have full reflectance in one resonance if the angle of incidence is sufficiently small. •Diffraction on a waveguiding 2D-grid is considered.•The type of the diffraction spectrum is determined by the filling factor and the degree of asymmetry of the grid’s cross section profile.•These two parameters constitute complex second Fourier harmonics of the material distribution in the grid.
AbstractList We study the resonances in transmission of a subwavelength dielectric lossless structure, periodic in one direction and infinite in the orthogonal (i.e. the effectively 2D problem). We are interested in the case of an encapsulated grid, deeply embedded into an optically-homogeneous surrounding medium. In the case, even a thin periodic structure, characterized by a positive relative excess of the refractive index, demonstrates full reflectance in a narrow bandwidth due to its waveguide capability. Here we systematically study all existing types of the diffraction spectra of the grids. We show that the diffraction type of the grid is determined by the geometric filling factor and the degree of asymmetry of the grid’s cross section profile. These two parameters are some linear functions of the complex amplitude of the second spatial Fourier harmonic of the material distribution in the grid. The amplitude determines the coupling between two resonant guiding modes. The coupling is relevant for relatively small angles of incidence, for which it substantially modifies the diffraction spectra in the vicinity of the resonances. Also, we revealed a particular type of diffraction grids, which show suppressed resonances at a relatively large angle of incidence but have full reflectance in one resonance if the angle of incidence is sufficiently small. •Diffraction on a waveguiding 2D-grid is considered.•The type of the diffraction spectrum is determined by the filling factor and the degree of asymmetry of the grid’s cross section profile.•These two parameters constitute complex second Fourier harmonics of the material distribution in the grid.
We study the resonances in transmission of a subwavelength dielectric lossless structure, periodic in one direction and infinite in the orthogonal (i.e. the effectively 2D problem). We are interested in the case of an encapsulated grid, deeply embedded into an optically-homogeneous surrounding medium. In the case, even a thin periodic structure, characterized by a positive relative excess of the refractive index, demonstrates full reflectance in a narrow bandwidth due to its waveguide capability. Here we systematically study all existing types of the diffraction spectra of the grids. We show that the diffraction type of the grid is determined by the geometric filling factor and the degree of asymmetry of the grid's cross section profile. These two parameters are some linear functions of the complex amplitude of the second spatial Fourier harmonic of the material distribution in the grid. The amplitude determines the coupling between two resonant guiding modes. The coupling is relevant for relatively small angles of incidence, for which it substantially modifies the diffraction spectra in the vicinity of the resonances. Also, we revealed a particular type of diffraction grids, which show suppressed resonances at a relatively large angle of incidence but have full reflectance in one resonance if the angle of incidence is sufficiently small.
ArticleNumber 100953
Author Perminov, S.V.
Efremova, E.A.
Vergeles, S.S.
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  givenname: E.A.
  surname: Efremova
  fullname: Efremova, E.A.
  email: ekaterina.efremova@metalab.ifmo.ru
  organization: ITMO University, Kronverksky Pr. 49, Bldg. A, St. Petersburg 197101, Russia
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  givenname: S.V.
  surname: Perminov
  fullname: Perminov, S.V.
  email: serge@isp.nsc.ru
  organization: A.V. Rzhanov Institute of Semiconductor Physics, Siberian Branch, Russian Academy of Sciences, 13 Lavrentyev Avenue, Novosibirsk 630090, Russia
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  givenname: S.S.
  surname: Vergeles
  fullname: Vergeles, S.S.
  email: ssver@itp.ac.ru
  organization: National Research University Higher School of Economics, Faculty of Physics, Myasnitskaya 20, 101000 Moscow, Russia
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Resonance waveguide grating
Mode coupling
Subwavelength dielectric structure
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Snippet We study the resonances in transmission of a subwavelength dielectric lossless structure, periodic in one direction and infinite in the orthogonal (i.e. the...
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SubjectTerms Amplitudes
Coupling
Diffraction grating
Encapsulation
Incidence angle
Linear functions
Mode coupling
Periodic structures
Reflectance
Refractivity
Resonance
Resonance waveguide grating
Subwavelength dielectric structure
Waveguides
Title Resonance behavior of diffraction on encapsulated guided-mode grating of subwavelength thickness
URI https://dx.doi.org/10.1016/j.photonics.2021.100953
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