Diffraction efficiency and guided light control by two-dimensional photonic band gap lattices

~Missing Data Labilloy; H Benisty; C Weisbuch; Thomas Fraser Krauss; D Cassagne; C Jouanin; R Houdre; U Oesterle; V Bardinal

Diffraction efficiency and guided light control by two-dimensional photonic band gap lattices

~Missing Data Labilloy, H Benisty, C Weisbuch, Thomas Fraser Krauss, D Cassagne, C Jouanin, R Houdre, U Oesterle, V Bardinal

School of Physics and Astronomy

Research output: Other contribution

Abstract

We report on the measurement of the diffraction efficiency of two-dimensional photonic-bandgap lattices consisting of a triangular array of circular air holes etched in a semiconductor waveguide, We use the spontaneous emission of the material as an internal point source. Combined with previous reflectivity and transmission measurements, the diffraction data allow us to assess the total amount of out-of-plane losses experienced by a guided wave traversing the dielectric lattice, as a function of the lattice pitch, We found that these losses are particularly weak for some range of parameters, especially in the photonic bandgap of interest. We discuss the reasons why they can be substantial with other parameters.

Original language	English
Volume	35
Publication status	Published - Jul 1999

Keywords

diffraction
luminescence
photonic crystals
radiation losses
scattering
semiconductor heterojunctions
spontaneous emission
waveguides
NEAR-INFRARED WAVELENGTHS
SPONTANEOUS EMISSION
WAVE-GUIDES
TRANSMISSION
GAP
CRYSTALS
MIRRORS

Cite this

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title = "Diffraction efficiency and guided light control by two-dimensional photonic band gap lattices",

abstract = "We report on the measurement of the diffraction efficiency of two-dimensional photonic-bandgap lattices consisting of a triangular array of circular air holes etched in a semiconductor waveguide, We use the spontaneous emission of the material as an internal point source. Combined with previous reflectivity and transmission measurements, the diffraction data allow us to assess the total amount of out-of-plane losses experienced by a guided wave traversing the dielectric lattice, as a function of the lattice pitch, We found that these losses are particularly weak for some range of parameters, especially in the photonic bandgap of interest. We discuss the reasons why they can be substantial with other parameters.",

keywords = "diffraction, luminescence, photonic crystals, radiation losses, scattering, semiconductor heterojunctions, spontaneous emission, waveguides, NEAR-INFRARED WAVELENGTHS, SPONTANEOUS EMISSION, WAVE-GUIDES, TRANSMISSION, GAP, CRYSTALS, MIRRORS",

author = "Labilloy, {~Missing Data} and H Benisty and C Weisbuch and Krauss, {Thomas Fraser} and D Cassagne and C Jouanin and R Houdre and U Oesterle and V Bardinal",

note = "IEEE Journ Quant Elec",

year = "1999",

month = jul,

language = "English",

volume = "35",

type = "Other",

}

TY - GEN

T1 - Diffraction efficiency and guided light control by two-dimensional photonic band gap lattices

AU - Labilloy, ~Missing Data

AU - Benisty, H

AU - Weisbuch, C

AU - Krauss, Thomas Fraser

AU - Cassagne, D

AU - Jouanin, C

AU - Houdre, R

AU - Oesterle, U

AU - Bardinal, V

N1 - IEEE Journ Quant Elec

PY - 1999/7

Y1 - 1999/7

N2 - We report on the measurement of the diffraction efficiency of two-dimensional photonic-bandgap lattices consisting of a triangular array of circular air holes etched in a semiconductor waveguide, We use the spontaneous emission of the material as an internal point source. Combined with previous reflectivity and transmission measurements, the diffraction data allow us to assess the total amount of out-of-plane losses experienced by a guided wave traversing the dielectric lattice, as a function of the lattice pitch, We found that these losses are particularly weak for some range of parameters, especially in the photonic bandgap of interest. We discuss the reasons why they can be substantial with other parameters.

AB - We report on the measurement of the diffraction efficiency of two-dimensional photonic-bandgap lattices consisting of a triangular array of circular air holes etched in a semiconductor waveguide, We use the spontaneous emission of the material as an internal point source. Combined with previous reflectivity and transmission measurements, the diffraction data allow us to assess the total amount of out-of-plane losses experienced by a guided wave traversing the dielectric lattice, as a function of the lattice pitch, We found that these losses are particularly weak for some range of parameters, especially in the photonic bandgap of interest. We discuss the reasons why they can be substantial with other parameters.

KW - diffraction

KW - luminescence

KW - photonic crystals

KW - radiation losses

KW - scattering

KW - semiconductor heterojunctions

KW - spontaneous emission

KW - waveguides

KW - NEAR-INFRARED WAVELENGTHS

KW - SPONTANEOUS EMISSION

KW - WAVE-GUIDES

KW - TRANSMISSION

KW - GAP

KW - CRYSTALS

KW - MIRRORS

M3 - Other contribution

VL - 35

ER -

Diffraction efficiency and guided light control by two-dimensional photonic band gap lattices

Abstract

Keywords

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