Quantitative Modeling of Gain in Quantum Cascade Lasers under Operational Intensities

David Winge

Quantitative Modeling of Gain in Quantum Cascade Lasers under Operational Intensities

David Winge

Research output: Thesis › Doctoral Thesis (compilation)

887 Downloads (Pure)

Abstract

This thesis adresses modeling of quantum cascade lasers using non-equilibrium Green’s functions. Focus lies on the quantitative modeling of the gain when the systems are exposed to strong laser fields, as under realistic opertional conditions. In the first part, an introduction to the general concepts is provided, together with a discussion on approximate analytic expressions. The second part consists of the six papers listed below.
Paper I analyzes the temperature dependence of the gain and current of a terahertz quantum cascade laser.
Paper II provides details of the implementiation of the non-equilibriun Green’s function formalism for simulations of transport in quantum cascade lasers.
Paper III demonstrates a microscopic approach to simulate the second harmonic generation of a mid-IR quantum cascade laser.
Paper IV documents the implementation of a rudimentary form of the GW-approximation for the electron-electron scattering self-energy.
Paper V analyzes a proposed gain mechanism in superlattices, and presents an optimized structure plausible for laser operation.
Paper VI shows simulation results of 16 samples from 5 different laboratories. From this systematic study, trends with repspect to the growth place are identified.

Original language	English
Qualification	Doctor
Supervisors/Advisors	Wacker, Andreas, Supervisor Samuelsson, Peter, Supervisor
Award date	2016 Nov 25
Place of Publication	Lund
Publisher	Lund University, Faculty of Science, Department of Physics, Division of Mathematical Physics
ISBN (Print)	978-91-7753-046-6
ISBN (electronic)	978-91-7753-047-3
Publication status	Published - 2016 Nov

Bibliographical note

Defence details
Date: 2016-11-25
Time: 13:15
Place: Physicum, Rydberg Lecture Hall, Sölvegatan 14A, Lund
External reviewer(s)
Name: Khurgin, Jacob B.
Title: Professor
Affiliation: Johns Hopkins University, Baltimore, USA
---

Subject classification (UKÄ)

Condensed Matter Physics (including Material Physics, Nano Physics)

Free keywords

non-linear response
quantum cascade lasers
modelling
Non-equilibrium Green's functions
Gain clamping
Fysicumarkivet A:2016:Winge

Access to Document

dw_thesis_part1Licence: CC BY

Simulating terahertz quantum cascade lasers: Trends from samples from different labs
Winge, D., Franckie, M. & Wacker, A., 2016 Sept 16, In: Journal of Applied Physics. 120, 114302.
Research output: Contribution to journal › Article › peer-review

Open Access
File
272 Downloads (Pure)
Simple electron-electron scattering in non-equilibrium Green's function simulations
Winge, D. O., Franckié, M., Verdozzi, C., Wacker, A. & Pereira, M. F., 2016 Apr 12, In: Journal of Physics: Conference Series. 696, 1, 012013.
Research output: Contribution to journal › Article › peer-review

Open Access
Superlattice gain in positive differential conductivity region
Winge, D. O., Franckié, M. & Wacker, A., 2016 Apr 1, In: AIP Advances. 6, 4, 045025.
Research output: Contribution to journal › Article › peer-review

Open Access

Cite this

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title = "Quantitative Modeling of Gain in Quantum Cascade Lasers under Operational Intensities",

abstract = "This thesis adresses modeling of quantum cascade lasers using non-equilibrium Green{\textquoteright}s functions. Focus lies on the quantitative modeling of the gain when the systems are exposed to strong laser fields, as under realistic opertional conditions. In the first part, an introduction to the general concepts is provided, together with a discussion on approximate analytic expressions. The second part consists of the six papers listed below. Paper I analyzes the temperature dependence of the gain and current of a terahertz quantum cascade laser. Paper II provides details of the implementiation of the non-equilibriun Green{\textquoteright}s function formalism for simulations of transport in quantum cascade lasers. Paper III demonstrates a microscopic approach to simulate the second harmonic generation of a mid-IR quantum cascade laser. Paper IV documents the implementation of a rudimentary form of the GW-approximation for the electron-electron scattering self-energy. Paper V analyzes a proposed gain mechanism in superlattices, and presents an optimized structure plausible for laser operation. Paper VI shows simulation results of 16 samples from 5 different laboratories. From this systematic study, trends with repspect to the growth place are identified. ",

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N2 - This thesis adresses modeling of quantum cascade lasers using non-equilibrium Green’s functions. Focus lies on the quantitative modeling of the gain when the systems are exposed to strong laser fields, as under realistic opertional conditions. In the first part, an introduction to the general concepts is provided, together with a discussion on approximate analytic expressions. The second part consists of the six papers listed below. Paper I analyzes the temperature dependence of the gain and current of a terahertz quantum cascade laser. Paper II provides details of the implementiation of the non-equilibriun Green’s function formalism for simulations of transport in quantum cascade lasers. Paper III demonstrates a microscopic approach to simulate the second harmonic generation of a mid-IR quantum cascade laser. Paper IV documents the implementation of a rudimentary form of the GW-approximation for the electron-electron scattering self-energy. Paper V analyzes a proposed gain mechanism in superlattices, and presents an optimized structure plausible for laser operation. Paper VI shows simulation results of 16 samples from 5 different laboratories. From this systematic study, trends with repspect to the growth place are identified.

AB - This thesis adresses modeling of quantum cascade lasers using non-equilibrium Green’s functions. Focus lies on the quantitative modeling of the gain when the systems are exposed to strong laser fields, as under realistic opertional conditions. In the first part, an introduction to the general concepts is provided, together with a discussion on approximate analytic expressions. The second part consists of the six papers listed below. Paper I analyzes the temperature dependence of the gain and current of a terahertz quantum cascade laser. Paper II provides details of the implementiation of the non-equilibriun Green’s function formalism for simulations of transport in quantum cascade lasers. Paper III demonstrates a microscopic approach to simulate the second harmonic generation of a mid-IR quantum cascade laser. Paper IV documents the implementation of a rudimentary form of the GW-approximation for the electron-electron scattering self-energy. Paper V analyzes a proposed gain mechanism in superlattices, and presents an optimized structure plausible for laser operation. Paper VI shows simulation results of 16 samples from 5 different laboratories. From this systematic study, trends with repspect to the growth place are identified.

KW - non-linear response

KW - quantum cascade lasers

KW - modelling

KW - Non-equilibrium Green's functions

KW - Gain clamping

KW - Fysicumarkivet A:2016:Winge

KW - kvantkaskadlaser

KW - terahertz

KW - infrarött

KW - Halvledarfysik

KW - spektroskopi

KW - simulering

M3 - Doctoral Thesis (compilation)

SN - 978-91-7753-046-6

PB - Lund University, Faculty of Science, Department of Physics, Division of Mathematical Physics

CY - Lund

ER -

Quantitative Modeling of Gain in Quantum Cascade Lasers under Operational Intensities

Abstract

Bibliographical note

Subject classification (UKÄ)

Free keywords

Access to Document

Fingerprint

Research output

Simulating terahertz quantum cascade lasers: Trends from samples from different labs

Simple electron-electron scattering in non-equilibrium Green's function simulations

Superlattice gain in positive differential conductivity region

Cite this