Optical properties of a laterally confined semiconductor microcavity containing a single quantum well

E. S. Lee; H. M. Gibbs; G. Khitrova

doi:10.1016/S1468-6996(03)00004-4

Optical properties of a laterally confined semiconductor microcavity containing a single quantum well

E. S. Lee, H. M. Gibbs, G. Khitrova

Optical Sciences, College of

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

Abstract

The semiconductor microcavity with a thin oxide-aperture layer is fabricated, and linear optical transmission spectrum measured for various aperture diameters. First, the observation of bare cavity modes is demonstrated in this microstructure which is capable of confining light field three-dimensionally. Several transverse modes are observed as transmission peaks, which manifests the lateral field confinement achieved well down to 2 μm aperture diameter. And the transmission spectrum of cavity modes coupled to the excitonic resonance is measured for the same microcavity system containing a single quantum well. The result shows that each transverse mode couples to an exciton independently as it approaches the excitonic resonance frequency, giving rise to an anti-crossing behavior between coupled modes.

Original language	English (US)
Pages (from-to)	13-17
Number of pages	5
Journal	Science and Technology of Advanced Materials
Volume	4
Issue number	1
DOIs	https://doi.org/10.1016/S1468-6996(03)00004-4
State	Published - 2003

Keywords

Distributed Bragg reflector
Exciton
Microcavity
Normal mode coupling
Optical mode
Oxide-aperture
Photonic device
Quantum well
Semiconductor microstructure

ASJC Scopus subject areas

Materials Science(all)

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10.1016/S1468-6996(03)00004-4

Cite this

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title = "Optical properties of a laterally confined semiconductor microcavity containing a single quantum well",

abstract = "The semiconductor microcavity with a thin oxide-aperture layer is fabricated, and linear optical transmission spectrum measured for various aperture diameters. First, the observation of bare cavity modes is demonstrated in this microstructure which is capable of confining light field three-dimensionally. Several transverse modes are observed as transmission peaks, which manifests the lateral field confinement achieved well down to 2 μm aperture diameter. And the transmission spectrum of cavity modes coupled to the excitonic resonance is measured for the same microcavity system containing a single quantum well. The result shows that each transverse mode couples to an exciton independently as it approaches the excitonic resonance frequency, giving rise to an anti-crossing behavior between coupled modes.",

keywords = "Distributed Bragg reflector, Exciton, Microcavity, Normal mode coupling, Optical mode, Oxide-aperture, Photonic device, Quantum well, Semiconductor microstructure",

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T1 - Optical properties of a laterally confined semiconductor microcavity containing a single quantum well

AU - Lee, E. S.

AU - Gibbs, H. M.

AU - Khitrova, G.

PY - 2003

Y1 - 2003

N2 - The semiconductor microcavity with a thin oxide-aperture layer is fabricated, and linear optical transmission spectrum measured for various aperture diameters. First, the observation of bare cavity modes is demonstrated in this microstructure which is capable of confining light field three-dimensionally. Several transverse modes are observed as transmission peaks, which manifests the lateral field confinement achieved well down to 2 μm aperture diameter. And the transmission spectrum of cavity modes coupled to the excitonic resonance is measured for the same microcavity system containing a single quantum well. The result shows that each transverse mode couples to an exciton independently as it approaches the excitonic resonance frequency, giving rise to an anti-crossing behavior between coupled modes.

AB - The semiconductor microcavity with a thin oxide-aperture layer is fabricated, and linear optical transmission spectrum measured for various aperture diameters. First, the observation of bare cavity modes is demonstrated in this microstructure which is capable of confining light field three-dimensionally. Several transverse modes are observed as transmission peaks, which manifests the lateral field confinement achieved well down to 2 μm aperture diameter. And the transmission spectrum of cavity modes coupled to the excitonic resonance is measured for the same microcavity system containing a single quantum well. The result shows that each transverse mode couples to an exciton independently as it approaches the excitonic resonance frequency, giving rise to an anti-crossing behavior between coupled modes.

KW - Distributed Bragg reflector

KW - Exciton

KW - Microcavity

KW - Normal mode coupling

KW - Optical mode

KW - Oxide-aperture

KW - Photonic device

KW - Quantum well

KW - Semiconductor microstructure

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JO - Science and Technology of Advanced Materials

JF - Science and Technology of Advanced Materials

SN - 1468-6996

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Optical properties of a laterally confined semiconductor microcavity containing a single quantum well

Abstract

Keywords

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