Semiconductor Quantum Dash Broadband Emitters: Modeling and Experiments

Broadband light emitters operation, which covers multiple wavelengths of the electromagnetic spectrum, has been established as an indispensable element to the human kind, continuously advancing the living standard by serving as sources in important multi-disciplinary field applications such as biome...

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Main Author: Khan, Mohammed Zahed Mustafa
Other Authors: Ooi, Boon S.
Language:en
Published: 2013
Subjects:
Online Access:http://hdl.handle.net/10754/311056
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spelling ndltd-kaust.edu.sa-oai-repository.kaust.edu.sa-10754-3110562015-10-22T03:37:16Z Semiconductor Quantum Dash Broadband Emitters: Modeling and Experiments Khan, Mohammed Zahed Mustafa Ooi, Boon S. Computer, Electrical and Mathematical Sciences and Engineering (CEMSE) Division Alshareef, Husam N. Helmy, Amr S. Kosel, Jürgen Semiconductor Laser Broadband Devices Quantum Dash Rate Equation Modeling Optoelectronic Devices Superluminescent Diodes Broadband light emitters operation, which covers multiple wavelengths of the electromagnetic spectrum, has been established as an indispensable element to the human kind, continuously advancing the living standard by serving as sources in important multi-disciplinary field applications such as biomedical imaging and sensing, general lighting and internet and mobile phone connectivity. In general, most commercial broadband light sources relies on complex systems for broadband light generation which are bulky, and energy hungry. Recent demonstration of ultra-broadband emission from semiconductor light sources in the form of superluminescent light emitting diodes (SLDs) has paved way in realization of broadband emitters on a completely novel platform, which offered compactness, cost effectiveness, and comparatively energy efficient, and are already serving as a key component in medical imaging systems. The low power-bandwidth product is inherent in SLDs operating in the amplified spontaneous emission regime. A quantum leap in the advancement of broadband emitters, in which high power and large bandwidth (in tens of nm) are in demand. Recently, the birth of a new class of broadband semiconductor laser diode (LDs) producing multiple wavelength light in stimulated emission regime was demonstrated. This very recent manifestation of a high power-bandwidth-product semiconductor broadband LDs relies on interband optical transitions via quantum confined dot/dash nanostructures and exploiting the natural inhomogeneity of the self-assembled growth technology. This concept is highly interesting and extending the broad spectrum of stimulated emission by novel device design forms the central focus of this dissertation. In this work, a simple rate equation numerical technique for modeling InAs/InP quantum dash laser incorporating the properties of inhomogeneous broadening effect on lasing spectra was developed and discussed, followed by a comprehensive experimental analysis of a novel epitaxial structure design. The layered structure is based on chirping the barrier layer thickness of the over grown quantum dash layer, in a multi-stack quantum dash/barrier active region, with the aim of inducing additional inhomogeneity. Based on material-structure and device characterization, enhanced lasing-emission bandwidth is achieved from the narrow (2 u m)ridge-waveguide LDs as a result of the formation of multiple ensembles of quantum dashes that are electronically different, in addition to improved device performance. Moreover, realization of SLDs from this device structure demonstrated extra-ordinary emission bandwidth covering the entire international telecommunication union (O- to U-) bands. This accomplishment is a collective emission from quantum wells and quantum dashes of the device active region. All these results lead to a step forward in the eventual realization of more than 150 nm lasing bandwidth from a single semiconductor laser diode. 2013-10 Dissertation http://hdl.handle.net/10754/311056 en
collection NDLTD
language en
sources NDLTD
topic Semiconductor Laser
Broadband Devices
Quantum Dash
Rate Equation Modeling
Optoelectronic Devices
Superluminescent Diodes
spellingShingle Semiconductor Laser
Broadband Devices
Quantum Dash
Rate Equation Modeling
Optoelectronic Devices
Superluminescent Diodes
Khan, Mohammed Zahed Mustafa
Semiconductor Quantum Dash Broadband Emitters: Modeling and Experiments
description Broadband light emitters operation, which covers multiple wavelengths of the electromagnetic spectrum, has been established as an indispensable element to the human kind, continuously advancing the living standard by serving as sources in important multi-disciplinary field applications such as biomedical imaging and sensing, general lighting and internet and mobile phone connectivity. In general, most commercial broadband light sources relies on complex systems for broadband light generation which are bulky, and energy hungry. Recent demonstration of ultra-broadband emission from semiconductor light sources in the form of superluminescent light emitting diodes (SLDs) has paved way in realization of broadband emitters on a completely novel platform, which offered compactness, cost effectiveness, and comparatively energy efficient, and are already serving as a key component in medical imaging systems. The low power-bandwidth product is inherent in SLDs operating in the amplified spontaneous emission regime. A quantum leap in the advancement of broadband emitters, in which high power and large bandwidth (in tens of nm) are in demand. Recently, the birth of a new class of broadband semiconductor laser diode (LDs) producing multiple wavelength light in stimulated emission regime was demonstrated. This very recent manifestation of a high power-bandwidth-product semiconductor broadband LDs relies on interband optical transitions via quantum confined dot/dash nanostructures and exploiting the natural inhomogeneity of the self-assembled growth technology. This concept is highly interesting and extending the broad spectrum of stimulated emission by novel device design forms the central focus of this dissertation. In this work, a simple rate equation numerical technique for modeling InAs/InP quantum dash laser incorporating the properties of inhomogeneous broadening effect on lasing spectra was developed and discussed, followed by a comprehensive experimental analysis of a novel epitaxial structure design. The layered structure is based on chirping the barrier layer thickness of the over grown quantum dash layer, in a multi-stack quantum dash/barrier active region, with the aim of inducing additional inhomogeneity. Based on material-structure and device characterization, enhanced lasing-emission bandwidth is achieved from the narrow (2 u m)ridge-waveguide LDs as a result of the formation of multiple ensembles of quantum dashes that are electronically different, in addition to improved device performance. Moreover, realization of SLDs from this device structure demonstrated extra-ordinary emission bandwidth covering the entire international telecommunication union (O- to U-) bands. This accomplishment is a collective emission from quantum wells and quantum dashes of the device active region. All these results lead to a step forward in the eventual realization of more than 150 nm lasing bandwidth from a single semiconductor laser diode.
author2 Ooi, Boon S.
author_facet Ooi, Boon S.
Khan, Mohammed Zahed Mustafa
author Khan, Mohammed Zahed Mustafa
author_sort Khan, Mohammed Zahed Mustafa
title Semiconductor Quantum Dash Broadband Emitters: Modeling and Experiments
title_short Semiconductor Quantum Dash Broadband Emitters: Modeling and Experiments
title_full Semiconductor Quantum Dash Broadband Emitters: Modeling and Experiments
title_fullStr Semiconductor Quantum Dash Broadband Emitters: Modeling and Experiments
title_full_unstemmed Semiconductor Quantum Dash Broadband Emitters: Modeling and Experiments
title_sort semiconductor quantum dash broadband emitters: modeling and experiments
publishDate 2013
url http://hdl.handle.net/10754/311056
work_keys_str_mv AT khanmohammedzahedmustafa semiconductorquantumdashbroadbandemittersmodelingandexperiments
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