Author:
Publisher:
ISBN:
Category :
Languages : en
Pages : 81
Book Description
Simulation of Quantum Cascade Lasers Made of GaAs
Author:
Publisher:
ISBN:
Category :
Languages : en
Pages : 81
Book Description
Publisher:
ISBN:
Category :
Languages : en
Pages : 81
Book Description
Deep-well GaAs- and InP-based Quantum Cascade Lasers for Mid-infared Emission
Author: Mithun D'Souza
Publisher:
ISBN:
Category :
Languages : en
Pages : 166
Book Description
Publisher:
ISBN:
Category :
Languages : en
Pages : 166
Book Description
Studies of GaAs Based Quantum Cascade Lasers
Author: Damian Andrew Carder
Publisher:
ISBN:
Category :
Languages : en
Pages :
Book Description
Publisher:
ISBN:
Category :
Languages : en
Pages :
Book Description
Design, Fabrication and Study of GaAs-based Mid-IR Quantum Cascade Lasers
Author: Zeila Zanolli
Publisher:
ISBN:
Category :
Languages : en
Pages : 126
Book Description
Publisher:
ISBN:
Category :
Languages : en
Pages : 126
Book Description
Software Design for Modeling Quantum Cascade Lasers and Long Wavelength (~16μm) GaAs/AlGaAs Quantum Cascade Lasers
Author: Ming Lyu
Publisher:
ISBN:
Category : Quantum optics
Languages : en
Pages : 0
Book Description
Publisher:
ISBN:
Category : Quantum optics
Languages : en
Pages : 0
Book Description
GaAs/AlGaAs Mid-infrared Quantum Cascade Laser
Author: Benjamin Stanford Williams
Publisher:
ISBN:
Category :
Languages : en
Pages : 115
Book Description
Publisher:
ISBN:
Category :
Languages : en
Pages : 115
Book Description
Quantum Cascade Lasers on AlGaAs-GaAs for the Mid-infrared Regime
Author: Stefan Gianordoli
Publisher:
ISBN:
Category :
Languages : en
Pages : 148
Book Description
Publisher:
ISBN:
Category :
Languages : en
Pages : 148
Book Description
Quantum Cascade Lasers
Author: Jérôme Faist
Publisher: OUP Oxford
ISBN: 0191663832
Category : Technology & Engineering
Languages : en
Pages : 321
Book Description
This book provides an introduction to quantum cascade lasers, including the basic underlying models used to describe the device. It aims at giving a synthetic view of the topic including the aspects of the physics, the technology, and the use of the device. It should also provide a guide for the application engineer to use this device in systems. The book is based on lecture notes of a class given for Masters and beginning PhD students. The idea is to provide an introduction to the new and exciting developments that intersubband transitions have brought to the use of the mid-infrared and terahertz region of the electromagnetic spectrum. The book provides an introductory part to each topic so that it can be used in a self-contained way, while references to the literature will allow deeper studies for further research.
Publisher: OUP Oxford
ISBN: 0191663832
Category : Technology & Engineering
Languages : en
Pages : 321
Book Description
This book provides an introduction to quantum cascade lasers, including the basic underlying models used to describe the device. It aims at giving a synthetic view of the topic including the aspects of the physics, the technology, and the use of the device. It should also provide a guide for the application engineer to use this device in systems. The book is based on lecture notes of a class given for Masters and beginning PhD students. The idea is to provide an introduction to the new and exciting developments that intersubband transitions have brought to the use of the mid-infrared and terahertz region of the electromagnetic spectrum. The book provides an introductory part to each topic so that it can be used in a self-contained way, while references to the literature will allow deeper studies for further research.
New Developments in GaAs-based Quantum Cascade Lasers
Author: Chris Atkins
Publisher:
ISBN:
Category :
Languages : en
Pages : 0
Book Description
Publisher:
ISBN:
Category :
Languages : en
Pages : 0
Book Description
Strained Indium Arsenide/gallium Arsenide Layers for Quantum Cascade Laser Design Using Genetic Algorithm
Author: David W. Mueller
Publisher:
ISBN:
Category :
Languages : en
Pages : 134
Book Description
Achieving high power, continuous wave, room temperature operation of midinfrared (3-5 [micrometer]) lasers is difficult due to the effects of auger recombination in band-to-band (type I) designs. Intersubband laser designs (type II) such as quantum cascade lasers reduce the effects of recombination, increasing efficiency and have advantages in large tunability of wavelength ranges (3 [micrometer] -25 [micrometer] and into the THz spectrum). Highly efficient quantum cascade laser designs are typically used in lasers designed for [greater than]5 [micrometer] wavelength operation due to the small offset of conduction band energy [delta]Ec in lattice matched materials. Some promising material systems have been used to achieve high-power output in the first atmospheric window (3-5 [micrometer]) but still suffer from low efficiency due to the lack of electron confinement. Larger [delta]Ec is attainable through the use of strained (lattice mis-matched) materials such as InGaAs/AlGaAs on GaAs. However, this material system has limitations on the traditional (100) crystal orientation due to the large strain and low critical thickness, hc. The necessity for controlled two-dimensional, optical quality layer growth limits the amount of strain incorporation due to defect formation in highly lattice mis-matched layers. The material systems used in this study are GaAs (100) and (111)B, AlGaAs, and (Ga)InAs. In the initial stage of research, I found that pseudomorphic growth of highly strained InAs layers on GaAs (111)B is possible. However, the growth window is very narrow and necessitates precise control over growth temperature and anion overpressure to achieve optical quality layers. As a result, a second stage of research explores the design space made available by this finding by using genetic algorithm based design and simulation of devices with a Schrödinger-Poisson solver - nextnano. This genetic algorithm is designed to rank candidate solutions on four important objectives for achieving novel QCL designs: operation between 3-5 [micrometer], Einj alignment just below E3, E2−E1 [almost equal to] ELO for optimal scattering for depopulation of carriers at the E2 energy level, and a gain metric [tau]3(1 − [tau]2/[tau]32). This approach was generally successful at finding unique designs, which have promise to work. However, since the algorithm ranked candidates based on only these four objectives, several interesting designs trends emerged. Many of the designs are far from the classic QCL structure and may not emit, however the trends help reveal the important design criteria. Discussion of this approach is compared to the traditional design philosophy and suggestions for improvement are centered around incorporating more objectives to guide the algorithm’s search. While improvements to the search mechanism are certainly necessary, several candidate solutions emerged and show great promise toward the goal of using this novel surface index and material system for efficient quantum cascade lasers that operate in the first atmospheric window.
Publisher:
ISBN:
Category :
Languages : en
Pages : 134
Book Description
Achieving high power, continuous wave, room temperature operation of midinfrared (3-5 [micrometer]) lasers is difficult due to the effects of auger recombination in band-to-band (type I) designs. Intersubband laser designs (type II) such as quantum cascade lasers reduce the effects of recombination, increasing efficiency and have advantages in large tunability of wavelength ranges (3 [micrometer] -25 [micrometer] and into the THz spectrum). Highly efficient quantum cascade laser designs are typically used in lasers designed for [greater than]5 [micrometer] wavelength operation due to the small offset of conduction band energy [delta]Ec in lattice matched materials. Some promising material systems have been used to achieve high-power output in the first atmospheric window (3-5 [micrometer]) but still suffer from low efficiency due to the lack of electron confinement. Larger [delta]Ec is attainable through the use of strained (lattice mis-matched) materials such as InGaAs/AlGaAs on GaAs. However, this material system has limitations on the traditional (100) crystal orientation due to the large strain and low critical thickness, hc. The necessity for controlled two-dimensional, optical quality layer growth limits the amount of strain incorporation due to defect formation in highly lattice mis-matched layers. The material systems used in this study are GaAs (100) and (111)B, AlGaAs, and (Ga)InAs. In the initial stage of research, I found that pseudomorphic growth of highly strained InAs layers on GaAs (111)B is possible. However, the growth window is very narrow and necessitates precise control over growth temperature and anion overpressure to achieve optical quality layers. As a result, a second stage of research explores the design space made available by this finding by using genetic algorithm based design and simulation of devices with a Schrödinger-Poisson solver - nextnano. This genetic algorithm is designed to rank candidate solutions on four important objectives for achieving novel QCL designs: operation between 3-5 [micrometer], Einj alignment just below E3, E2−E1 [almost equal to] ELO for optimal scattering for depopulation of carriers at the E2 energy level, and a gain metric [tau]3(1 − [tau]2/[tau]32). This approach was generally successful at finding unique designs, which have promise to work. However, since the algorithm ranked candidates based on only these four objectives, several interesting designs trends emerged. Many of the designs are far from the classic QCL structure and may not emit, however the trends help reveal the important design criteria. Discussion of this approach is compared to the traditional design philosophy and suggestions for improvement are centered around incorporating more objectives to guide the algorithm’s search. While improvements to the search mechanism are certainly necessary, several candidate solutions emerged and show great promise toward the goal of using this novel surface index and material system for efficient quantum cascade lasers that operate in the first atmospheric window.