Two-dimensional Penrose-tiled photonic quasicrystals: From diffraction pattern to band structure

MA Kaliteevski; S Brand; RA Abram; Thomas Fraser Krauss; R De La Rue; P Millar

doi:10.1088/0957-4484/11/4/316

Two-dimensional Penrose-tiled photonic quasicrystals: From diffraction pattern to band structure

MA Kaliteevski, S Brand, RA Abram, Thomas Fraser Krauss, R De La Rue, P Millar

School of Physics and Astronomy

Research output: Contribution to journal › Article › peer-review

Abstract

We report measurements of the diffraction pattern of a two-dimensional photonic quasicrystal structure and use the set of plane waves defined by the diffraction pattern as the basis of a theoretical approach to calculate the photonic band structure of the system. An important feature of the model is that it retains the essence of the rotational and inflational properties of the quasicrystal at all levels of approximation: properties lost in approximate models which artificially introduce elements of periodicity.

The calculated density of modes of the quasicrystals is found to display a weakly depleted region analogous to the bandgap that occurs in a periodic system. The calculated transmission spectra for different polarizations and directions of propagation show features that correlate with the behaviour of the density of modes.

Original language	English
Pages (from-to)	274-280
Number of pages	7
Journal	Nanotechnology
Volume	11
Issue number	4
DOIs	https://doi.org/10.1088/0957-4484/11/4/316
Publication status	Published - Dec 2000

Keywords

QUASI-CRYSTALS
SYMMETRY
PHASE

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10.1088/0957-4484/11/4/316

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abstract = "We report measurements of the diffraction pattern of a two-dimensional photonic quasicrystal structure and use the set of plane waves defined by the diffraction pattern as the basis of a theoretical approach to calculate the photonic band structure of the system. An important feature of the model is that it retains the essence of the rotational and inflational properties of the quasicrystal at all levels of approximation: properties lost in approximate models which artificially introduce elements of periodicity.The calculated density of modes of the quasicrystals is found to display a weakly depleted region analogous to the bandgap that occurs in a periodic system. The calculated transmission spectra for different polarizations and directions of propagation show features that correlate with the behaviour of the density of modes.",

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AU - Abram, RA

AU - Krauss, Thomas Fraser

AU - De La Rue, R

AU - Millar, P

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N2 - We report measurements of the diffraction pattern of a two-dimensional photonic quasicrystal structure and use the set of plane waves defined by the diffraction pattern as the basis of a theoretical approach to calculate the photonic band structure of the system. An important feature of the model is that it retains the essence of the rotational and inflational properties of the quasicrystal at all levels of approximation: properties lost in approximate models which artificially introduce elements of periodicity.The calculated density of modes of the quasicrystals is found to display a weakly depleted region analogous to the bandgap that occurs in a periodic system. The calculated transmission spectra for different polarizations and directions of propagation show features that correlate with the behaviour of the density of modes.

AB - We report measurements of the diffraction pattern of a two-dimensional photonic quasicrystal structure and use the set of plane waves defined by the diffraction pattern as the basis of a theoretical approach to calculate the photonic band structure of the system. An important feature of the model is that it retains the essence of the rotational and inflational properties of the quasicrystal at all levels of approximation: properties lost in approximate models which artificially introduce elements of periodicity.The calculated density of modes of the quasicrystals is found to display a weakly depleted region analogous to the bandgap that occurs in a periodic system. The calculated transmission spectra for different polarizations and directions of propagation show features that correlate with the behaviour of the density of modes.

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ER -

Two-dimensional Penrose-tiled photonic quasicrystals: From diffraction pattern to band structure

Abstract

Keywords

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