Nanosecond tandem optical parametric oscillators for mid-infrared generation

Henriksson, Markus

January 2007

This thesis discusses a new scheme for generating radiation in the mid infrared spectral region, especially the 3.5-5 µm range. The scheme uses established Nd3+-lasers at 1.06 µm and down conversion in nonlinear optical crystals. The down conversion is made by two optical parametric oscillators (OPO) in series. The second OPO is a classical OPO using a zink germanium phosphide (ZGP) crystal. ZGP is the best nonlinear material available for the 4-8 µm spectral range, but it is absorbing below 2 µm. The new development presented in this thesis is the OPO used to convert the 1.06 µm laser radiation to a suitable OPO pump near 2 µm. The OPO uses a type I quasi phase-matched crystal, which accesses high nonlinearities and avoids walk-off. The problem with type I OPOs close to degeneracy is the broad bandwidth of the generated radiation, which reduces the efficiency of a second OPO. This has been solved with a spectrally selective cavity using a volume Bragg grating output coupler. Unlike other bandwidth limiting schemes this introduces no intracavity losses and thus efficient OPO operation is achievable. Narrow linewidth (~0.5 nm) OPO operation has been achieved with periodically poled LiNbO3 (PPLN) and periodically poled KTiOPO4 (PPKTP) while locking the signal wavelength at 2008 nm and simultaneously generating an idler at 2264 nm. A high average power PPLN OPO with 36 % conversion efficiency and 47 % slope efficiency is reported. Operation very close to degeneracy at 2128 nm with the narrowband signal and idler peaks separated by 0.6 nm was demonstrated in a PPKTP OPO. Both the signal at 2008 nm and the combined signal and idler around 2128 nm from the PPKTP OPOs have been used to show efficient pumping of a ZGP OPO. The maximum conversion efficiency from 1 µm to the mid-IR demonstrated is 7 % with a slope efficiency of 10 %. This is not quite as high as what has been presented by other authors, but the experiments reported here have not shown the optimum efficiency of the new scheme. Relatively simple improvements are expected to give a significant increase in conversion efficiency. / QC 20101108

nonlinear optics

optical parametric oscillators

quasi-phase matching

mid-infrared

linewidth narrowing

volume Bragg gratings.

Physical Sciences

Fysik

High-speed Modelocked Semiconductor Lasers And Applications In Coherent Photonic Systems

Lee, Wangkuen

01 January 2007

1.55-µm high-speed modelocked semiconductor lasers are theoretically and experimentally studied for various coherent photonic system applications. The modelocked semiconductor lasers (MSLs) are designed with high-speed (>5 GHz) external cavity configurations utilizing monolithic two-section curved semiconductor optical amplifiers. By exploiting the saturable absorber section of the monolithic device, passive or hybrid mode-locking techniques are used to generate short optical pulses with broadband optical frequency combs. Laser frequency stability is improved by applying the Pound-Drever-Hall (PDH) frequency stabilization technique to the MSLs. The improved laser performance after the frequency stabilization (a frequency drifting of less than 350 MHz), is extensively studied with respect to the laser linewidth (~ 3 MHz), the relative intensity noise (RIN) (< -150 dB/Hz), as well as the modal RIN (~ 3 dB reduction). MSL to MSL, and tunable laser to MSL synchronization is demonstrated by using a dual-mode injection technique and a modulation sideband injection technique, respectively. Dynamic locking behavior and locking bandwidth are experimentally and theoretically studied. Stable laser synchronization between two MSLs is demonstrated with an injection seed power on the order of a few microwatt. Several coherent heterodyne detections based on the synchronized MSL systems are demonstrated for applications in microwave photonic links and ultra-dense wavelength division multiplexing (UD-WDM) system. In addition, efficient coherent homodyne balanced receivers based on synchronized MSLs are developed and demonstrated for a spectrally phase-encoded optical CDMA (SPE-OCDMA) system.

Modelocking

External Cavity Semiconductor Laser

High-Speed Photonics

RIN

PDH

Linewidth

Coherent Detection

Analog Links

WDM

OCDMA

Electromagnetics and Photonics

Optics

Development of MAS solid state NMR methods for structural and dynamical characterization of biomolecules

Shevelkov, Veniamin

10 January 2011

Das Verständnis der Mechanismen, nach denen biologische Systeme ablaufen, ist ein wichtiger Fokus der aktuellen Strukturbiologie. Kernmagnetische Resonanzspektroskopie (NMR) ist eine geeignete Technik, um solche Ziele anzustreben sowie Struktur und Dynamik von Biomolekülen zu erforschen, um komplementäre Informationen zum Verständnis von Proteinfunktionalität zu erhalten. Rasante Fortschritte sind vor nicht langer Zeit auf dem Gebiet biologischer Festkörper-NMR (ssNMR) erzielt worden, was zu vollständiger Strukturaufklärung zahlreicher Peptide und kleiner Proteine, der Beschreibung von Protein-Komplexbildung sowie der der dynamischen Eigenschaften kleiner Proteine geführt hat. Festkörper-NMR ist die Methode der Wahl bei struktureller und dynamischer Charakterisierung von Membranproteinen und aggregierten amyloidogenen Systemen, die schwer löslich und kaum mit Lösungs-NMR oder Röntgenkristallographie zugänglich sind. Moderne Festkörper-NMR ist noch immer limitiert, was Auflösung und Empfindlichkeit betrifft, und macht weitere Entwicklungen auf den Gebieten der Probenpräparation und des Pulssequenz-Designs erforderlich. In meiner Arbeit untersuche ich die potenzielle Verwendung von Deuterierung in der Protein Festkörper-NMR zur Erhöhung von Empfindlichkeit und Auflösung in 15N-1H Korrelationsexperimenten. Der erzielte Fortschritt auf diesen Gebieten erlaubt die Verfolgung von Proteinrückgratbewegungen mit hoher Genauigkeit, die vorher nicht verfügbar war. Wir zeigen zum ersten Mal, dass TROSY Experimente für Festkörper-NMR gewinnbringend sind. Außerdem wurde eine Pulssequenz für 13C-13C J Kopplung zur Erhöhung der Auflösung in der Kohlenstoff-Dimension entwickelt. / Understanding the mechanisms how biological systems work is an important objective of current structural biology. Nuclear magnetic resonance (NMR) spectroscopy is a well suited technique to approach these goals and to study structure and dynamics of biomolecules in order to obtain complimentary information for understanding functionality of proteins. Recently, rapid progress has been made in the field of biological solid state NMR (ssNMR), which resulted in complete structure elucidation of several peptides and small proteins, the characterization of protein complex formation and the characterization of dynamic properties of small proteins. Solid state NMR is the method of choice for structural and dynamic characterization of membrane proteins and aggregated amyloidogenic systems, which are poorly soluble and can not be easily studied by solution state NMR and X-ray spectroscopy. Modern solid state NMR is still limited in resolution and sensitivity, and requires developments in sample preparation and pulse sequence design. In my thesis, I study the potential use of deuteration in protein solid state NMR for sensitivity, as well as for resolution enhancement in 15N-1H correlation experiments. Achieved progress in these fields allows to monitor backbone motion with high accuracy, which has not been available before. We show for the first time that TROSY type experiments can be beneficial for solid state NMR. In addition, a pulse sequence for 13C-13C J decoupling was developed to increase resolution in the carbon dimension.

Festkörper-NMR-Spektroskopie

Linienbreite

Perdeuterierung

Dynamik von Proteinen

Solid state NMR spectroscopy

Linewidth

Perdeuteration

Dynamics of proteins

570 Biowissenschaften, Biologie

32 Biologie

WC 3460

ddc:570

Efeito do tratamento térmico na relaxação magnética de microfios amorfos de CoFeSiB recobertos por vidro / Effect joule-heated in the magnetic relaxation amorphous glass-covered microwires

Chrischon, Dieivase da Silva

27 February 2012

Magnetoimpedance has been proved to be an excellent tool to study the magnetization dynamics and the ferromagnetic resonance (FMR) linewidth provides a convenient way for measuring damping parameters in magnetic materials. The FMR linewidth depends on intrinsic magnetic damping and additional magnetic inhomogeneities, but complete understanding of the origin of these damping parameters is still unaccomplished. Besides the fundamental physics interest, the study of damping term and magnetization dynamics is very important for the development of any device which has its physical effect associated with the reversal of magnetization. Furthermore, the FMR linewidth is a very sensitive way to study the structural quality of magnetic samples, in both bulk and thin film geometries. In this work the magnetic relaxation of CoFeSiB glass-covered microwire was investigated by ferromagnetic resonance (FMR) linewidth measurements. We have identified the main damping mechanisms and quantified these damping terms, showing the effect of annealing temperature to them. The study have shown that there are three main damping mechanisms responsible for the FMR linewidth, the Gilbert damping parameter, a damping mechanism due to anisotropy dispersions and two-magnon scattering. The Gilbert damping parameter is almost constant and not influenced by the annealing. The FMR linewidth is very sensitive to anisotropy dispersions and this mechanism has a great contribution to the magnetic relaxation. The two-magnon scattering is an assignment of the inhomogeneities present in the samples and its contribution to the FMR linewidth decrease with the annealing temperature until a critical value, as a result of a decrease of inhomogeneities due to a reduction of the internal stress level. A further increase in the annealing temperature produces an increase in the two-magnon scattering contribution which is an indication of the growing of nanocrystals acting as scattering centers to the spin waves. / Magnetoimpedância tem provado ser uma excelente ferramenta para estudar a dinâmica de magnetização e a largura de linha da ressonância ferromagnética (FMR) fornece uma maneira conveniente para medir parâmetros de amortecimento em materiais magnéticos. A largura de linha FMR depende do amortecimento magnético intrínseco e adicionais inomogeneidades magnéticas, mas o completo entendimento da origem destes parâmetros de amortecimento ainda está inacabado. Além do interesse da física fundamental, o estudo da dinâmica de amortecimento e magnetização é muito importante para o desenvolvimento de qualquer dispositivo que tem seu efeito físico associado com a inversão da magnetização. Além disso, a largura de linha FMR é uma forma muito sensível para estudar a qualidade estrutural de amostras magnéticas. Neste trabalho é apresentado um estudo da relaxação magnética de microfios amorfos de CoFeSiB recobertos por vidro, mostrando o efeito da temperatura de recozimento sobre as propriedades magnéticas do microfio. Foram identificados e quantificados os principais mecanismos de amortecimento, mostrando o efeito da temperatura de recozimento para eles. Os estudos mostraram que existem três principais mecanismos de amortecimento responsável pela largura de linha FMR: o parâmetro de amortecimento de Gilbert; um mecanismo de amortecimento devido à dispersões na anisotropia; e o amortecimento devido ao espalhamento de magnons. O parâmetro de amortecimento de Gilbert é quase constante e não influenciado pelo recozimento. A largura de linha FMR é muito sensível a dispersões da anisotropia e esse mecanismo tem uma grande contribuição para o relaxamento magnético. A dispersão de magnons é uma atribuição de inomogeneidades presentes nas amostras e tem contribuição para a diminuição da largura de linha com a temperatura de recozimento até um valor crítico, como resultado de uma diminuição de inomogeneidades devido a uma redução do nível de estresse interno. Um aumento na temperatura de recozimento produz um aumento na contribuição de espalhamento dos magnons, que é uma indicação do crescimento de nanocristais atuando como centros de dispersão para as ondas de spin.

Microfios

Ressonância ferromagnética

Largura de linha FMR

Magnetoimpedancia

Dinâmica de magnetização

Microwires

Ferromagnetic resonance

FMR linewidth

Magnetoimpedance

Magnetization dynamics

CNPQ::CIENCIAS EXATAS E DA TERRA::FISICA

Development and study of low noise laser diodes emitting at 894 nm for compact cesium atomic clocks / Développement et étude de diodes laser à faible bruit émettant à 894 nm pour horloges atomiques compactes au Césium

Von Bandel, Nicolas

30 June 2017

Ce travail de thèse porte sur la conception, la réalisation et l'étude de sources laser à semi-conducteur de haute cohérence, émettant à 894 nm, pour application aux horloges atomiques Césium compactes pompées optiquement, dans un contexte de développement industriel. Nous nous intéressons plus particulièrement aux lasers à émission par la tranche, dits "Distributed-Feedback" (DFB), pompés électriquement. L'objectif est d'obtenir un laser monomode en fréquence, à faible seuil, à rendement optique élevé et de largeur de raie inférieure à 1 MHz. Nous traitons d'abord de la conception et de la caractérisation au 1er ordre des diodes DFB, jusqu'à leur mise en modules pour horloge, puis nous effectuons une étude approfondie des propriétés physiques de l'émission laser en terme de cohérence temporelle, en introduisant une nouvelle méthode universelle de caractérisation du bruit de fréquence optique. Enfin, nous nous intéressons aux propriétés spectrales de l'émission en configuration d'asservissement sur une raie de fluorescence du Césium ("Dither-Locking"). Nous montrons que les propriétés intrinsèques du composant satisfont aux exigences du système industriel tel qu'il a été défini lors de l'étude. / This PhD work deals with the design, the fabrication and the study of high-coherence semiconductor laser sources emitting at 894 nm, for application to compact, optically-pumped cesium atomic clocks in an industrial context. We are particularly interested in the electrically pumped "Distributed-Feedback" in-plane laser diodes (DFB). The aim is to obtain a low-threshold, single-mode laser with high optical efficiency and a linewidth of less than 1 MHz. We first deal with the design and first-order characterization of the DFB diodes until they are put into modules for the clock. We then carry out an in-depth study of the physical properties of the laser emission in terms of coherence time. For that purpose, a new universal method for characterizing the optical frequency noise is introduced. Finally, we look further into the spectral properties of the emission in a servo configuration on a fluorescence line of the cesium ("Dither-Locking"). We show that the intrinsic properties of the component satisfy the requirements of the industrial system as defined in the study.

Diodes laser

Faible bruit

894nm

Horloges atomiques au Césium

Métrologie du bruit de fréquence

Largeur de raie en asservissement

Laser diodes

Low noise

894nm

Cesium atomic clocks

Frequency noise metrology

Linewidth in servo

Měření základních parametrů optických a optoelektronických komponent / Measurement of basic parameters of optical and optoelectronic components

Beneš, Pavel

January 2021

This diploma thesis deals with optical and optoelecronic components. The first part of the work describes the optical paths and methods of their measurement. The second part describes the coupler, circulator and isolator. Further described is a laser diode, a photodetector and a modulator. The third part describes the measurement procedure of the coupler, circulator, isolator, laser diode, photodetector and modulator. The measured values are compared with the catalog values.

Développement des sources lasers solides continues, visibles et stabilisées en fréquence : une alternative aux lasers à colorants / Development of solid state CW visible and frequency stabilized laser sources : an alternative to dye lasers

Mhibik, Oussama

05 December 2011

Le traitement de l’information quantique, en particulier celui utilisant les centres colorés du diamant et la manipulation cohérente des ions de terre rare incorporés dans des matrices solides (Pr3+, Eu3+) et la spectroscopie à ultra-haute résolution, nécessitent des sources accordables ayant une faible largeur de raie. Or, dans la gamme rouge-orange (570-635 nm) où les diodes lasers font défaut et les lasers solides restent très peu développés, les lasers à colorants sont actuellement les seules sources de rayonnement cohérent disponibles. En revanche, ce type de laser est assez complexe et difficile à stabiliser au niveau du kHz à cause des bruits à haute fréquence générés par le jet de colorant.Pour répondre aux besoins des expériences citées ci-dessus, cette thèse vise à proposer une alternative “tout solide” aux lasers à colorants en explorant différentes possibilités pour la construction d’une source stable émettant dans l’orange-rouge. Dans ce but, nous avons proposé deux solutions:1. La première consiste à développer des oscillateurs paramétriques optiques. Dans cette voie, nous avons développé un OPO simplement résonant à doublage de fréquence intra-cavité et stabilisé en frequence au niveau du kHz.2. La deuxième consiste en un laser à base de fluorures dopés au Pr3+pompé par diode. / The quantum information processing using diamond color center or the coherent manipulation of rare earth ion embedded in solid state matrices (Pr3+, Eu3+) or the high resolution spectroscopy, require narrow linewidth tunable laser sources.However in the orange-red range (570-635 nm) where laser diodes are lacking and solid-state lasers are poorly developed, only dye lasers are currently available. Nevertheless these sources are complex and difficult to stabilize at the kHz level because of the high frequency noise induced by dye jet.The aim of this thesis is to give an all-solid state alternative of dye lasers. For this purpose, two solutions have been studied:1. The first approach consists on the development of an intracavity frequency doubled singly resonant optical parametric oscillator (OPO) and frequency stabilized at the kHz level.2. The second approach consists on the development of a diode pumped Pr-doped fluoride laser.

Optique non-linéaire

OPO

Information quantique

Ions de terre rare

Largeur de raie

Ion praséodyme

Fluorures

Laser solide

Diode laser

Nonlinear optics

OPO

Quantum information

Rare earth ion

Linewidth

Prseodymium

Fluorides

Solid state laser

Laser diode

Développement de diodes laser à faible largeur de raie pour le pompage atomique et d'un MOPA (Master Oscillator Power Amplifier) à 780 nm pour le refroidissement d'atomes de Rubidium et la réalisation de capteurs inertiels / Development of laser diodes with narrow linewidth for atomic pumping and a MOPA (Master Oscillator Power Amplifier)at 780 nm for cooling Rubidium atoms and realization of inertial sensors

Bebe Manga Lobe, Joseph Patient

24 April 2015

Cette thèse de doctorat a été réalisée au sein du III-VLab, en partenariat avec l’Institut d’Electronique du Sud (IES). L’objectif de ce travail de thèse vise d’une part à l’optimisation des performances des diodes laser DFB émettant à 780 nm et le développement d’une source plus compacte (MOPA) à 780nm, intégrant de façon monolithique l’oscillateur maître (laser à rétro-action répartie ou DFB) et l’amplificateur de puissance, et d’autre part, à appréhender les phénomènes de bruit, permettant d’évaluer la qualité technologique des lasers. Les développements autour de la longueur d’onde 780 nm, se sont organisés en plusieurs thématiques : les lasers Fabry-Perot et DFB, les amplificateurs (SOA), les MOPA et l’étude du bruit des lasers. Nous avons étudié des structures de différentes épaisseurs de puits quantiques (160Å, 135 Å et 145 Å). La comparaison des performances globales des différentes structures de lasers larges, loin d’être évidente, nous a permis de choisir celle intégrant un puits quantique de 160 Å, pour la réalisation des lasers Fabry-Perot à ruban étroit (3µm à 4µm). Nous avons obtenu sur des lasers larges, de 3 mm de long, bruts de clivage, une puissance d’environ 5 watts par face pour un courant d’injection continu autour de 10 A. Les simulations et caractérisations électro-optiques menées sur des lasers ridge Fabry-Perot, ont servi à affiner le dessin des DFB à 780 nm, par rapport aux briques de base existantes du III-V Lab, et à proposer des structures à cavités optiques larges et super-large (LOC et SLOC) optimisées, en termes de puissance, qualités de faisceau et spectrale.Les mesures de bruits, appuyées d’un modèle de bruit électrique, ont permis d’extraire une valeur du paramètre de Hooge de 2,1.10^-3 pour les lasers ridge, en accord avec la littérature, et qui correspond à une bonne qualité de matériau et technologique des lasers. Différents types d’amplificateurs optiques évasés ont été dessinés, réalisés et caractérisés. Les caractérisations des diverses géométries de SOA, ont donné dans l’ensemble, des valeurs de gain comprises entre 19dB et 25dB. Nous avons obtenu respectivement pour les structures d’amplificateurs à guidages entièrement par l’indice (GI), entièrement par le gain (GG) et mixte (GM), des puissances de 500mW, 750mW et 1W. L’ensemble des résultats obtenus avec ces structures sont prometteurs pour l’intégration monolithique avec le DFB. En ce qui concerne le MOPA, trois approches ont été étudiées: MOPA droit, DFB et amplificateur tiltés de 7° (par rapport à la normale aux faces clivées), et la plus prometteuse mais plus complexe, intégrant le DFB droit et l’amplificateur tilté de 7°, avec une section courbe entre les deux. La prise en compte de l’ensemble des résultats lasers Fabry-Perot, DFB et des résultats d’amplificateurs, nous ont permis de proposer des dessins MOPA originaux. Le dessin du masque réalisé, intègre toutes ces configurations de MOPA, et en plus, des SOA et DFB, qui seront utilisés comme témoins de test lors des caractérisations. / This thesis has been realized in III-VLab in collaboration with the South Electronic Institute in Montpellier. The aim of this work focuses in one hand, on the performance improvement of DFB's diode lasers emitting at 780 nm, and the advanced design of a compact semiconductor laser diode (Master Oscillator Power Amplifier), integrating monolithically the master oscillator (DFB for Distributed Feedback laser); in the other hand, using the noise phenomenon’s studies as a tool, for validating of our laser technologies. The Developments round the 780 nm wavelength, have been divided into different thematic: Fabry-Perot and DFB, Semiconductor Optical Amplifiers (SOA), MOPA, and the lasers noise’s study. We have studied structures with different quantum well thickness (160Å, 135 Å and 145 Å). The comparison of global performances of broad area lasers from these different structures, far to being obvious, allowed us to choose the one that integrates the 160-Å-thickness of quantum-well, for the realization of ridge Fabry-Perot lasers of 3 to 4-µm-of width. We obtained with broad area lasers, as cleaved, with 3-mm cavity lengths, an output power around 5 watts per facet, in continuous bias current around 10 AModellings and electro-optics characterizations performed on ridge Fabry-Perot lasers, allowed to refine DFB lasers at 780 nm, in comparison of the existing building blocks in the lab; we proposed new optimized structures with Large and Super Large Optical Cavities(LOC and SLOC), in terms of optical output power, beam and spectral qualities.The noise measurements with electrical noise modelling, allowed us to extract a value of Hooge’s parameter of 2,1.10^-3, quite in agreement with literature for such lasers, which corresponds to a good material quality and laser technology.Different types of flared SOA have been designed, realized and characterized. The characterizations of various SOA geometries, have given in general, values of gain between 19 dB to 25 dB. With SOAs of types: fully Index Guiding (IG), fully Gain Guiding (GG) and Mixed Guiding (MG), we have respectively obtained 500 mW, 750 mW and 1 W. All the results obtained with these structures are promising for monolithic integration with DFB. Regarding the MOPA, three approaches have been studied. The straight MOPA, the approach of SOA and DFB with 7° tilt(relative to the normal to cleaved facets), and the most complex, but promising approach, integrating the SOA with 7° tilt, and straight DFB, with a bend section between them. By taking into account all the results obtained on Fabry-Perot lasers, DFB, and SOA results, we were able to propose original MOPA designs. The layout drawing has been realized, all the MOPA configurations and additional, DFB and SOA devices, have been included on it. They will be used as test structures for characterizations.

Senseurs inertiels

Pompage atomique

Refroidissement d'atomes

Diodes laser 780 nm

Largeur de raie

Inertial sensors

Atomic pumping

Cooling of atoms

780 nm lasers

Linewidth

MOPA : Master Oscillator Power-Amplifier

High-speed Properties of 1.55-micron-wavelength Quantum Dot Semiconductor Amplifiers and Comparison with Higher-Dimensional Structures

Zilkie, Aaron John

26 February 2009

This thesis reports an experimental characterization of the ultrafast gain and refractive index dynamics of a novel InAs/InGaAsP/InP quantum-dot (QD) semiconductor optical amplifier (SOA) operating near 1.55-µm wavelengths, assessing its high-speed performance characteristics for the first time. The thesis also studies the influence of the degree of quantum confinement on the dynamics of SOAs by comparing the zero-dimensional (0-D) QD's dynamics to those in 1-D InAs/InAlGaAs/InP quantum-dash (QDash), and 2-D InGaAsP/InGaAsP/InP quantum-well (QW) SOAs, both of which also operate near 1.55-µm wavelengths, and are made with matching or similar materials and structures. The ultrafast (around 1 ps) and long-lived (up to 2 ns) amplitude and phase dynamics of the SOAs are characterized via advanced heterodyne pump-probe measurements with 150-femtosecond resolution. It is found that the QD SOA has an 80-picosecond amplitude, and 110-picosecond phase recovery lifetime in the gain regime, 4-6 times faster than the QDash and QW recovery lifetimes, as well as reduced ultrafast transients, giving it the best properties for high-speed (> 100 Gb/s) all-optical signal processing in the important telecommunications wavelength bands. An impulse response model is developed and used to analyze the dynamics, facilitating a comparison of the gain compression factors, time-resolved linewidth enhancement factors (alpha-factors), and instantaneous dynamic coefficients (two-photon absorption and nonlinear refractive-index coefficients) amongst the three structures. The quantum-dot device is found to have the lowest effective alpha-factor, 2-10, compared to 8-16 in the QW, as well as time-resolved alpha-factors lower than in the QW—promising for reduced-phase-transient operation at high bitrates. Significant differences in the alpha-factors of lasers with the same structure are found, due to the differences between gain changes that are induced optically or through the electrical bias. The relative contributions of stimulated transitions and free-carrier absorption to the total carrier heating dynamics in SOAs of varying dimensionality are also reported for the first time. Examining the QD electroluminescence and linear gain spectra in combination with the carrier dynamics also brings about conclusions on the nature of the quantum confinement, dot energy-level structure, and density of states—aspects of the material that have not been previously well understood.

quantum dot

semiconductor optical amplifiers

all-optical switching

semiconductor nonlinear dynamics

semiconductor lasers

nonlinear optics

semiconductor physics

linewidth enhancement factor

two-photon absorption

quantum well

quantum dash

ultrafast lasers

optical signal processing

0544

High-speed Properties of 1.55-micron-wavelength Quantum Dot Semiconductor Amplifiers and Comparison with Higher-Dimensional Structures

Zilkie, Aaron John

26 February 2009

This thesis reports an experimental characterization of the ultrafast gain and refractive index dynamics of a novel InAs/InGaAsP/InP quantum-dot (QD) semiconductor optical amplifier (SOA) operating near 1.55-µm wavelengths, assessing its high-speed performance characteristics for the first time. The thesis also studies the influence of the degree of quantum confinement on the dynamics of SOAs by comparing the zero-dimensional (0-D) QD's dynamics to those in 1-D InAs/InAlGaAs/InP quantum-dash (QDash), and 2-D InGaAsP/InGaAsP/InP quantum-well (QW) SOAs, both of which also operate near 1.55-µm wavelengths, and are made with matching or similar materials and structures. The ultrafast (around 1 ps) and long-lived (up to 2 ns) amplitude and phase dynamics of the SOAs are characterized via advanced heterodyne pump-probe measurements with 150-femtosecond resolution. It is found that the QD SOA has an 80-picosecond amplitude, and 110-picosecond phase recovery lifetime in the gain regime, 4-6 times faster than the QDash and QW recovery lifetimes, as well as reduced ultrafast transients, giving it the best properties for high-speed (> 100 Gb/s) all-optical signal processing in the important telecommunications wavelength bands. An impulse response model is developed and used to analyze the dynamics, facilitating a comparison of the gain compression factors, time-resolved linewidth enhancement factors (alpha-factors), and instantaneous dynamic coefficients (two-photon absorption and nonlinear refractive-index coefficients) amongst the three structures. The quantum-dot device is found to have the lowest effective alpha-factor, 2-10, compared to 8-16 in the QW, as well as time-resolved alpha-factors lower than in the QW—promising for reduced-phase-transient operation at high bitrates. Significant differences in the alpha-factors of lasers with the same structure are found, due to the differences between gain changes that are induced optically or through the electrical bias. The relative contributions of stimulated transitions and free-carrier absorption to the total carrier heating dynamics in SOAs of varying dimensionality are also reported for the first time. Examining the QD electroluminescence and linear gain spectra in combination with the carrier dynamics also brings about conclusions on the nature of the quantum confinement, dot energy-level structure, and density of states—aspects of the material that have not been previously well understood.

quantum dot

semiconductor optical amplifiers

all-optical switching

semiconductor nonlinear dynamics

semiconductor lasers

nonlinear optics

semiconductor physics

linewidth enhancement factor

two-photon absorption

quantum well

quantum dash

ultrafast lasers

optical signal processing

0544