Superradiant mode and photonic band of a one-dimensional resonant Bragg reflector

P. Renucci; T. Amand; X. Marie; P. Sellenart; J. Bloch; B. Sermage

doi:10.1002/1521-396X(200204)190:2<401::AID-PSSA401>3.0.CO;2-F

Superradiant mode and photonic band of a one-dimensional resonant Bragg reflector

P. Renucci
, T. Amand
, X. Marie
, P. Sellenart
, J. Bloch
, B. Sermage

École Polytechnique

Research output: Contribution to journal › Conference article › peer-review

Abstract

Based on a most general framework of dispersion equation for EM waves in a periodic system which contains both the effects of resonant levels and Bragg reflection, we have derived the dispersion equations of polaritons in the 1D resonant Bragg reflector (lattice constant equal to one half of the resonant wavelength). This equation gives a gap mode in the middle of the lowest photonic gap, which does not exist in the dispersion derived from a transfer matrix in the absence of nonradiative damping. The evolution of the superradiant (SR) mode is discussed as a function of the layer number N of the Bragg reflector from the reflectance in frequency and time domains. The frequency dependence of radiative correction is shown to be essential to obtain the consistent picture of the SR mode (small N) and photonic band formation (large N) in the whole range of N.

Original language	English
Pages (from-to)	401-405
Number of pages	5
Journal	physica status solidi (a)
Volume	190
Issue number	2
DOIs	https://doi.org/10.1002/1521-396X(200204)190:2<401::AID-PSSA401>3.0.CO;2-F
Publication status	Published - 1 Apr 2002
Event	7th International Conference on Optics and Excitons in Confined Systems - Montpellier, France Duration: 3 Sept 2001 → 7 Sept 2001

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Cite this

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title = "Superradiant mode and photonic band of a one-dimensional resonant Bragg reflector",

abstract = "Based on a most general framework of dispersion equation for EM waves in a periodic system which contains both the effects of resonant levels and Bragg reflection, we have derived the dispersion equations of polaritons in the 1D resonant Bragg reflector (lattice constant equal to one half of the resonant wavelength). This equation gives a gap mode in the middle of the lowest photonic gap, which does not exist in the dispersion derived from a transfer matrix in the absence of nonradiative damping. The evolution of the superradiant (SR) mode is discussed as a function of the layer number N of the Bragg reflector from the reflectance in frequency and time domains. The frequency dependence of radiative correction is shown to be essential to obtain the consistent picture of the SR mode (small N) and photonic band formation (large N) in the whole range of N.",

author = "P. Renucci and T. Amand and X. Marie and P. Sellenart and J. Bloch and B. Sermage",

year = "2002",

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TY - JOUR

T1 - Superradiant mode and photonic band of a one-dimensional resonant Bragg reflector

AU - Renucci, P.

AU - Amand, T.

AU - Marie, X.

AU - Sellenart, P.

AU - Bloch, J.

AU - Sermage, B.

PY - 2002/4/1

Y1 - 2002/4/1

N2 - Based on a most general framework of dispersion equation for EM waves in a periodic system which contains both the effects of resonant levels and Bragg reflection, we have derived the dispersion equations of polaritons in the 1D resonant Bragg reflector (lattice constant equal to one half of the resonant wavelength). This equation gives a gap mode in the middle of the lowest photonic gap, which does not exist in the dispersion derived from a transfer matrix in the absence of nonradiative damping. The evolution of the superradiant (SR) mode is discussed as a function of the layer number N of the Bragg reflector from the reflectance in frequency and time domains. The frequency dependence of radiative correction is shown to be essential to obtain the consistent picture of the SR mode (small N) and photonic band formation (large N) in the whole range of N.

AB - Based on a most general framework of dispersion equation for EM waves in a periodic system which contains both the effects of resonant levels and Bragg reflection, we have derived the dispersion equations of polaritons in the 1D resonant Bragg reflector (lattice constant equal to one half of the resonant wavelength). This equation gives a gap mode in the middle of the lowest photonic gap, which does not exist in the dispersion derived from a transfer matrix in the absence of nonradiative damping. The evolution of the superradiant (SR) mode is discussed as a function of the layer number N of the Bragg reflector from the reflectance in frequency and time domains. The frequency dependence of radiative correction is shown to be essential to obtain the consistent picture of the SR mode (small N) and photonic band formation (large N) in the whole range of N.

UR - https://www.scopus.com/pages/publications/0036544478

U2 - 10.1002/1521-396X(200204)190:2<401::AID-PSSA401>3.0.CO;2-F

DO - 10.1002/1521-396X(200204)190:2<401::AID-PSSA401>3.0.CO;2-F

M3 - Conference article

AN - SCOPUS:0036544478

SN - 0031-8965

VL - 190

SP - 401

EP - 405

JO - physica status solidi (a)

JF - physica status solidi (a)

IS - 2

T2 - 7th International Conference on Optics and Excitons in Confined Systems

Y2 - 3 September 2001 through 7 September 2001

ER -

Superradiant mode and photonic band of a one-dimensional resonant Bragg reflector

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