Existence of two-dimensional absolute photonic band gaps in the visible

Barra, Anthony; Cassagne, D.; Jouanin, C.

doi:10.1063/1.120827

Cited by 29 publications

(17 citation statements)

References 13 publications

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“…Assume the dielectric modulation to be only on the z -y plane and in-plane wave propagation. The structure consisting of parallel, infinitely long air cylinders in a dielectric background, arranged in a triangular lattice, was shown to be the optimal case [37], together with the one consisting of dielectric cylinders in air arranged in the graphite structure [38]. Experiments done in the microwave regime [39,40] showed excellent agreement with the theoretical predictions.…”

Section: Photonic Band Gap Materialssupporting

confidence: 71%

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Wave propagation in ordered, disordered, and nonlinear photonic band gap materials

Lidorikis

1999

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Section: Photonic Band Gap Materialssupporting

confidence: 71%

“…for a triangular arrangement of air cylinders in dielectric [37] and for a graphite arrangement of solid dielectric cylinders in air [38].…”

Section: E(f)mentioning

confidence: 99%

Wave propagation in ordered, disordered, and nonlinear photonic band gap materials

Lidorikis

1999

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“…The electromagnetic wave propagation inside a PC is forbidden for some specific or all directions for a certain frequency range due to the photonic bandgap (PBG) effect [1]. However, it has been reported that there is anisotropy of PBG in PC caused by the low-level rotational symmetry in its Brillouin zone [2], [3]. Higher rotational symmetry leads to more circular Brillouin zone and less anisotropy of PBG.…”

mentioning

confidence: 99%

Octagonal Quasi-Photonic Crystal Single-Defect Microcavity With Whispering Gallery Mode and Condensed Device Size

Lee

Tsai

2007

IEEE Photon. Technol. Lett.

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Abstract-We propose a new single-defect microcavity which supports well-confined whispering gallery mode in octagonal quasiphotonic crystals (OQPC) by shifting the eight nearest air holes around the cavity. Lasing action is observed and compared with the calculated results obtained using the finite-difference time-domain method. We also investigate the threshold dependence on the number of lattice periods of this OQPC microcavity and compare it with triangular lattice photonic crystal (PC) microcavity with similar cavity size. The OQPC microcavity exhibits only a 36% increase of threshold when the number of lattice periods decreases from eight to four, which is more advantageous than the triangular lattice PC microcavity for the shrinkage of device size.

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“…This would provide the ideal PBG structure for the use in applications where the inhibition of spontaneous emission is desirable. It is firmly established that periodic triangular and hexagonal lattice structures can support complete photonic bandgaps in 2D and 3D [4][5][6]. However, complete and absolute PBGs (CAPBGs) have only been achieved in very high dielectric constant materials like GaAs (m= 13.6) using hexagonal lattice structures [6].…”

Section: Introductionmentioning

confidence: 99%

“…For many applications involving the use of PCs it is desirable to acquire complete and absolute photonic bandgaps [4]. In the case of such PBG structures, the wave propagation is forbidden for any direction of propagation, and independent of the polarisation state.…”

Section: Introductionmentioning

confidence: 99%

Complete and absolute photonic bandgaps in highly symmetric photonic quasicrystals embedded in low refractive index materials

Zoorob

Charlton

Parker

et al. 2000

Materials Science and Engineering: B

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It is firmly established that periodic lattice structures can support photonic bandgaps (PBG). However, complete and absolute photonic bandgaps (CAPBG) have only been achieved in high dielectric constant mediums such as GaAs (m = 13.6). An artificial quasiperiodic photonic crystal based on the random square-triangle tiling system was designed and fabricated. The photonic quasicrystal possesses 12-fold symmetry and was analysed using a finite difference time domain (FDTD) approach. High orders of symmetry in photonic quasicrystals have been shown to provide isotropic bandgaps across all the directions of propagation of light. As an outcome of these properties, this new class of photonic quasicrystal has been shown, for the first time, to possess a secondary non-directional CAPBG for a relatively low index material, silicon nitride (m = 4.08). These materials are compatible with integrated optical technologies. This allows the fabrication of efficient integrated optical PBG devices such as WDM filters and multiplexers to become a real possibility.

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Existence of two-dimensional absolute photonic band gaps in the visible

Cited by 29 publications

References 13 publications

Wave propagation in ordered, disordered, and nonlinear photonic band gap materials

Wave propagation in ordered, disordered, and nonlinear photonic band gap materials

Octagonal Quasi-Photonic Crystal Single-Defect Microcavity With Whispering Gallery Mode and Condensed Device Size

Complete and absolute photonic bandgaps in highly symmetric photonic quasicrystals embedded in low refractive index materials

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