Pattern recognition and tomographic reconstruction with Terahertz Signals for applications in biomedical engineering.

Yin, Xiaoxia (Sunny)

January 2009

Over the last ten years, terahertz (THz or T-ray) biomedical imaging has become a modality of interest due to its ability to simultaneously acquire both image and spectral information. Terahertz imaging systems are being commercialized, with increasing trials performed in a biomedical setting. Advanced digital image processing algorithms are greatly need to assist screening, diagnosis, and treatment. Pattern recognition algorithms play a critical role in the accurate and automatic process of detecting abnormalities when applied to biomedical imaging. This goal requires classification of meaningful physical contrast and identification of information in images, for example, distinguishing between different biological tissues or materials. T-ray tomographic imaging and detection technology contributes especially to our ability to discriminate opaque objects with clear boundaries and makes possible significant potential applications in both in vivo and ex vivo environments. The Thesis consists of a number of Chapters, which can be grouped in to three parts. The first part provides a review of the state-of-the-art regarding THz sources and detectors, THz imaging modes, and THz imaging analysis. Pattern recognition forms the second part of this Thesis, which is represented via combining several basic operations: wavelet transforms and wavelet based signal filtering, feature extraction and selection, along with classification schemes for THz applications. Signal filtering in this Thesis is achieved via wavelet based de-noising. The ultrafast pulses generated terahertz time-domain spectroscopy (THz-TDS), which is demonstrated to justify their decomposition in the wavelet domain as it can provide better de-noising performance. Feature extraction and selection of the terahertz measurements rely on observed changes in pulse amplitude and phase, as well as scattering characteristics of several different types of powder samples under study. Additionally, three signal processing algorithms are adopted for the evaluation of the complex insertion loss function of such samples as lactose, mandelic acid, and dl-mandelic acid: (i) standard evaluation by ratioing the sample with the background spectra, (ii) a subspace identification algorithm, and (iii) a novel wavelet packet identification procedure. These system identification algorithms enable THz measurements to be transformed to features for THz pattern recognition. Meanwhile, a novel feature extraction method involving the use of Auto Regressive (AR) and Auto Regressive Moving Average (ARMA)models on the wavelet transforms of measured T-ray pulse responses of ex vivo osteosarcoma cells as well as other biomedical materials is presented. Classification schemes are carried out via simple and robust schemes, such as the linear Mahalanobis distance classifier, and the non-linear Support Vector Machine (SVM) classifier. In particular, SVMs are used as a learning scheme to achieve the identification of two classes of RNA samples and multiple classes of powered materials. Coherent terahertz detection hardware—THz time-domain spectroscopy (THz-TDS)—is used to obtain all the data for validation of these classification schemes. The past decade has witnessed the tremendous development of terahertz instruments for detecting, storing, analysing, and displaying images. Terahertz time-domain spectroscopy (THz-TDS) is a broadband technique that generates and detects THz radiation in a synchronous and coherent manner. By contrast, the newly developed THz quantum cascade laser is a narrow-band radiation source that provides potential for realising compact systems; they produce image data with higher average power levels. The third part of this Thesis discusses methods to improve the capability of both broad and narrow-band terahertz imaging, driven by computer-aided analytical techniques. A wavelet based reconstruction algorithm for terahertz computed tomography is represented to show how this algorithm can be used to rapidly reconstruct the region of interest (ROI) with a reduction in the measurements of terahertz responses, compared with a standard filtered back-projection technique. These reconstruction algorithms are applied to the analysis of acquired experimental data and to locally recover the two dimensional (2D) and three-dimensional (3D) structures of several optically opaque objects. Moreover, a segmentation technique based on two dimensional wavelet transforms is investigated for the identification of different materials from the reconstructed CT image. / http://proxy.library.adelaide.edu.au/login?url= http://library.adelaide.edu.au/cgi-bin/Pwebrecon.cgi?BBID=1352839 / Thesis (Ph.D.) - University of Adelaide, School of Electrical and Electronic Engineering, 2009

Mesures par spectrométrie laser des flux de N2O et CH4 produits par les sols agricoles et viticoles / Measurement by laser spectrometry of N2O fluxes producted by agricultural and viticultural soil

Mappe fogaing, Irene

28 March 2013

Depuis l'ère industrielle, les émissions des gaz à effet de serre, responsables du réchauffement climatique majoritairement d'origine anthropique, ne cessent d'augmenter. Parmi ces gaz, les principaux concernés sont le dioxyde de carbone (CO2), le protoxyde d'azote (N2O) et le méthane (CH4).Dans le cadre de ma thèse, nous allons nous intéresser majoritairement au N2O et aussi au CH4, qui malgré leurs plus faibles quantités dans l'atmosphère, ils ont un potentiel de réchauffement global largement supérieur à celui du CO2.Ces rejets gazeux anthropiques suffisent à provoquer des modifications climatiques à court ou moyen terme. Il est donc nécessaire de comprendre les phénomènes liés à ces émissions. De nombreux réseaux européens tels que Euroflux, CarboEuroflux, NitroEurope, CarboEurope, GHG-Europe et ICOS ont activement contribué à la quantification et la compréhension des émissions des gaz à effet de serre. Il subsiste cependant d'importantes incertitudes sur les bilans inter annuels de ces émissions. Afin de mieux assimiler la variabilité temporelle des émissions de N2O et CH4, il est indispensable de les mesurer continuellement dans le temps en fonction des écosystèmes, des types de sol, et de disposer d'instruments de mesure performants. Le GSMA grâce à ses compétences en instrumentation, a développé un spectromètre utilisant un laser à cascade quantique, QCLAS (Quantum Cascade Laser Absorption Spectrometer), dédié à la mesure in situ de flux de gaz produits par les sols. Comme dans toute expérimentation, les mesures faites par QCLAS peuvent être contaminées de bruits. Ces bruits peuvent entraîner des biais sur les valeurs de flux calculés. C'est la raison pour laquelle on s'intéressera aux méthodes d'analyses des signaux telles que les transformées en ondelettes, la décomposition en valeurs singulières, dont l'utilisation aura pour objectif d'extraire l'information utile des signaux, et permettra d'améliorer significativement le rapport signal à bruit ainsi que la dispersion des mesures. Cette thèse est organisée en trois principales parties : la première est consacrée dans un premier temps aux techniques usuelles de mesure de gaz, où nous introduirons l'instrument QCLAS. On verra ensuite trois techniques usuelles de mesure de flux à savoir : la technique des enceintes closes, l'Eddy corrélation, et le relaxed Eddy accumulation. La seconde partie portera sur les différentes procédures et méthodes de traitement pour l'optimisation de la mesure expérimentale. La dernière partie portera sur les différentes campagnes de mesures réalisées avec QCLAS. Ces applications montreront la robustesse de QCLAS ainsi que son aptitude à effectuer des mesures de terrain. / Since the industrial revolution, emissions of greenhouse gases (GHG) responsible for global warming, mainly anthropogenic, continue to increase. Among these gases, the main concerned are carbon dioxide (CO2 ), nitrous oxide (N2O ) and methane (CH4 ).In my thesis, we will focus mainly on N2O and CH4 , which despite their smaller quantities in the atmosphere, have a global warming potential higher than the CO2. These anthropogenic gas emissions are sufficient to cause climatic change in the short or medium term. It is therefore necessary to understand the phenomena linked to these emissions.Many European networks such as Euroflux, CarboEuroflux, NitroEurope, CarboEurope GHG-Europe and ICOS have actively contributed to the understanding and quantification of greenhouse gases emissions. However it remains considerable uncertainty about the inter-annual balance sheets of these emissions. To better assimilate the temporal variability of N2O and CH4 emissions, it is necessary to measure continuously over time in terms of ecosystems, soil types, and to have performance measurement tools. The GSMA with its expertise in instrumentation, has developed a spectrometer using a quantum cascade laser, QCLAS (Quantum Cascade Laser Absorption Spectrometer), designed to measure in situ gas flow produced by the soil. As in any experiment, QCLAS measurements may be contaminated by noise. These noises can cause biases in fluxes determination. This is why we will focus on signal proccessing methods such as wavelet transform, singular value decomposition, with the purpose of extracting useful signal informations and significantly improving the signal to noise ratio and the dispersion of measurements. This thesis is organized in three main parts: The first part is devoted first to conventional techniques for gas measurements, where we will introduce the instrument QCLAS. Then, we will examine three usual techniques of flow measurement namely: the technique of closed chambers, Eddy correlation and relaxed Eddy accumulation. The second part will focus on the different procedures and treatment methods to optimize experimental measurements. The last part will focus on the various measurements campaigns made with QCLAS. These applications demonstrate the robustness of QCLAS as well as its ability to perform field measurements.

Spectrométrie

Laser à cascade quantique

Mesure de flux

Spectrometry

Quantum cascade laser

Fluxes meaasurements

Lasers à cascade quantique moyen infrarouge à base d'InAs / Mid-infrared quantum cascade laser on InAs

Laffaille, Pierre

11 December 2013

Les lasers à cascade quantique sont des sources lasers à semiconducteur compactes et capables de délivrer une forte puissance optique sur une large gamme de longueur d'onde dans l'infrarouge. Les QCLs de la filière InP sont les plus établis. Le système de matériaux InAs/AlSb est une solution alternative encore peu développée mais qui, en vertu de ses propriétés, présente des atouts incontestables pour la réalisation de lasers à cascade quantique. Le travail de cette thèse a apporté une meilleure connaissance du système InAs/AlSb et de ses possibilités pour les QCLs, à la fois sur un plan théorique, expérimental et technologique.Nous avons œuvré à l'amélioration des performances des lasers à cascade quantique sur ce système de matériaux, notamment en cherchant à augmenter la température maximum de fonctionnement dans les courtes longueurs d'onde et le lointain infrarouge. Un modèle de transport électronique a été développé. Ce modèle permet de reproduire de manière relativement précise les résultats expérimentaux. Il est un outil utile pour l'amélioration des designs de zone active et, en conséquence, des performances des lasers.La finalité de ces lasers est leur utilisation pour des applications telles que la spectroscopie moléculaire par absorption. Nous avons donc travaillé à les rendre plus adaptés aux besoins de celles-ci, à savoir que leur émission soit monomode, ce que nous avons rendu possible grâce au développement d'une technologie DFB à haut rendement et très reproductible, et qu'ils puissent fonctionner en régime continu, ce qui a été accompli, autour de 9 µm de longueur d'onde d'émission, jusqu'à une température de 255 K en s'appuyant sur un modèle prédictif basé sur une approche analytique.Afin d'atteindre le fonctionnement en régime continu en dessous de 4 µm de longueur d'onde, nous nous sommes penchés sur l'utilisation d'un substrat alternatif en GaSb, qui nous permet de réaliser des claddings conciliant un faible indice de réfaction et de faibles pertes optiques. Nous avons à cette occasion fait la démonstration du premier QCL fonctionnant sur ce substrat, et ce jusqu'à température ambiante à 3,3 µm de longueur d'onde. / Quantum cascade lasers (QCLs) are unipolar semiconductor lasers employing radiative transitions between electron subbands in multiple quantum well structures. QCLs can deliver high optical powers in a large spectral range from mid-IR to THz. The best QCL performances have been achieved using III-V materials that can be grown on InP substrates. The InAs/AlSb material system represents an alternative solution for the elaboration of QCLs. While it is still much less explored compared with the InP family, some properties of these materials are very attractive for the development of QCLs.This thesis contributed to better understanding of the InAs/AlSb system, as well as to physics and technology QCLs based on these materials.Much attention has been paid to the performance improvement of InAs/AlSb QCLs, especially to the increasing of operation temperature of these lasers. A model of electronic transport in such devices, which is in good agreement with obtained experimental data, has been developed. This model has been used for optimization of the QCL design and, in consequence, to the improvement of the lasers performances.The main application of infrared lasers is molecular spectroscopy requiring high spectral purity of the laser emission. To make InAs-based QCLs suitable for spectroscopic applications we have developed a technology of distributed feedback (DFB) lasers for the 3-10 µm range with single frequency emission. Continuous wave (cw) operation of InAs/AlSb QCLs has been achieved for the first time in lasers emitting near 9 µm at temperatures up to 255 K. These lasers have been optimized for cw operation using predictive modeling of heat balance in the device. In order to improve performances of short wavelength InAs/AlSb QCLs emitting below 4 µm we proposed to replace a plasmon enhanced waveguide employing heavily doped InAs and exhibiting strong free carrier absorption by a low loss dielectric waveguide with AlGaSbAs cladding layers. These lasers grown for the first time on GaSb substrates and operated between 2.8 and 3.3 µm demonstrated performances proving the attractiveness of this approach to achieve further progress in InAs/AlSb QCLs.

Laser à cascade quantique

Intersousbande

Antimoniures

Moyen infrarouge

Quantum cascade laser

Intersubband

Antimonides

Mid-infrared

Optique intégrée pour sources largement accordables moyen-infrarouge / Integrated optics for broadly tunable mid infrared sources

Gilles, Clément

19 January 2017

Dans le moyen-infrarouge, les barrettes de lasers à cascade quantique sont d’un grand intérêt pour la réalisation de sources large bande intégrables dans les systèmes de spectroscopie laser. Une excellente finesse spectrale, la présence d’un seul mode spatial et une gamme d’accordabilité large sont ainsi rassemblées sur une seule puce, compacte et intrinsèquement stable. Afin de bénéficier de l’ensemble des longueurs d’onde sur une sortie unique, les défis majeurs résident dans l’association de technologies pour rassembler les différentes sorties en une seule via l’utilisation de circuits photoniques intégrés (CPI). Ce CPI peut être séparé en trois briques élémentaires : une filière de guidage passif, un combineur de longueurs d’onde et un coupleur actif/passif. Pour la mise-en-forme du faisceau, nous reportons la fabrication et la caractérisation de guides d’onde en InP/InGaAs/InP gravés profondément, avec des performances proches de l’état de l’art. Nous fabriquons et caractérisons des multiplexeurs basés sur des réseaux de diffraction intégrés, sur filière InP et SiGe. Un multiplexeur de 60-vers-1 voies couvrant la gamme de 7-8,5 µm est réalisé. Une méthode innovante mettant en œuvre des multiplexeurs inter-digités et fonctionnant sur trois ordres de diffraction est démontrée. Finalement, nous réalisons des barrettes de laser à cascade quantique sur InP et sur silicium. Un coupleur adiabatique est dimensionné, fabriqué et caractérisé pour associer efficacement les guides actifs et passifs. Des intégrations de types hétérogène et hybride sont envisagées, avec la première démonstration d’une source accordable utilisant une barrette de lasers et un multiplexeur InP. / In the mid-infrared, arrays of distributed feedback quantum cascade lasers have been developed as a serious alternative to obtain extended wavelength operation range of laser-based gas sensing systems. Narrow-linewidth, single mode operation and wide tunability are then gathered together on a single chip with high compactness and intrinsic stability. In order to benefit from this extended wavelength range in a single output beam, the key challenge resides in the combination of different technologies to merge the output of different sources via the use of mid-IR photonic integrated circuits (PIC). The PIC can be split into three main blocks: the passive waveguide platform, the beam combiner and the active/passive coupler. For beam handling and guiding, we report fabrication and characterization of deeply etched InP/InGaAs/InP waveguides with state of the art performances. We fabricate and characterize multiplexers based on echelle and arrayed waveguide gratings on InP and SiGe platforms. A 60-to-1 spectral multiplexer operating in the 7-to-8.5 µm range is demonstrated. An advanced multiplexing scheme using interleaved and cross-order operations is also exposed. Finally, we realize quantum cascade laser arrays on InP and silicon. We design, fabricate and characterize an adiabatic coupler to efficiently and monolithically integrate active and passive waveguides. Heterogenous and hybrid integration are also considered with the demonstration of a tunable source using laser array and InP-based multiplexer.

Photonique intégrée

Laser à cascade quantique

Moyen infrarouge

Integrated optics

Mid-Infrared

Quantum cascade laser

Mid-infrared InGaAs/InAlAs Quantum Cascade Lasers / 中赤外InGaAs/InAlAs量子カスケードレーザに関する研究

Fujita, Kazuue

24 September 2014

京都大学 / 0048 / 新制・論文博士 / 博士(工学) / 乙第12860号 / 論工博第4107号 / 新制||工||1609(附属図書館) / 31540 / (主査)教授 北野 正雄, 教授 川上 養一, 准教授 酒井 道 / 学位規則第4条第2項該当 / Doctor of Philosophy (Engineering) / Kyoto University / DFAM

Mid-infrared laser

Quantum cascade laser

Intersubband transition

Semiconductor laser

Semiconductor superlattice

500

Ultra compact ans sensitive Terahertz Heterodyne receiver based on quantum cascade laser and hot electron bolometer / Détection Hétérodyne compacte et ultra-sensible à base de lasers à cascade quantique et de bolomètre à électron chaud

Joint, François

12 December 2018

Nous avons développé un récepteur hétérodyne terahertz (THz) compact et ultra-sensible à base de laser à cascade quantique (QCL) comme oscillateur local et de bolomètre à électron chaud (HEB) comme mélangeur. Le récepteur est basé sur un nouveau concept pour le couplage quasi-optique entre l'oscillateur local et le mélangeur ce qui a permis de ne pas utiliser de lame semi-réfléchissante pour la superposition du signal provenant du QCL et du signal à détecter. Le mélangeur utilisé est un HEB en nitrure de niobium avec une antenne planaire formée d’une double hélice log-spiral. Le HEB est monté sur la partie plane d’une lentille convexe en silicium. L’oscillateur local est un QCL que nous avons développé avec un système de contre-réaction répartie du troisième ordre avec une faible dissipation thermique, un faisceau peu divergent et un fonctionnement mono-mode à la fréquence cible de 2.7 THz. Le couplage entre l’oscillateur local et le mélangeur HEB a également été amélioré en couplant le QCL avec une fibre creuse en diélectrique ce qui a permis d’améliorer la directivité du faisceau laser à 55 dBi. Grâce aux précédents résultats, nous avons obtenu un récepteur THz hétérodyne compact qui présente une sensibilité proche de l’état de l’art à 2.7 THz. / We demonstrate an ultra-compact Terahertz (THz) heterodyne detec- tion system based on a quantum cas- cade laser (QCL) as local oscillator and a hot electron bolometer (HEB) for the mixing. It relies on a new opti- cal coupling scheme where the local oscillator signal is coupled through the air side of the planar HEB an- tenna, while the signal to be de- tected is coupled to the HEB through the lens. This technique allows us to suppress the beam splitter usu- ally employed for heterodyne mea- surements. The mixer is a Niobium Nitride HEB with a log-spiral planar antenna on silicon and mounted on the back of a plano-convex silicon lens. We have developed a low power consumption and low beam di- vergence 3rd-order distributed feed- back laser with single mode emis- sion at the target frequency of 2.7 THz to be used as local oscillator for the heterodyne receiver. The cou- pling between the QC laser and the the HEB has been further optimized, using a dielectric hollow waveguide that reliably increases the laser beam directivity up to 55 dBi. Upon the high beam quality, sufficient output power in a single mode at the tar- geted frequency and low power dissi- pation of our local oscillator, we have build an ultra compact THz hetero- dyne receiver with sensitivity close to the state of the art at 2.7 THz.

Détection Hétérodyne

Bolomètre à Electron Chaud

Laser à cascade quantique

Heterodyne Detection

Hot Electron Bolometer

Quantum Cascade Laser

520

Novel on-line mid infrared detection strategies in capillary electrophoretic systems

Kölhed, Malin

January 2005

<p>Infrared absorption spectra can provide analytically useful information on a large variety of compounds, ranging from small ions to large biological molecules. In fact, all analytes that possess a dipole moment that changes during vibration are infrared-active. The infrared (IR) spectrum can be subdivided into far-, mid- and near- regions. The focus of attention in this thesis is the mid-IR region, in which the fundamental vibrations of most organic compounds are located, thus providing scope for positive structural identification. However, while such near-ubiquitous signals can be very useful for monitoring simple molecules in simple systems, they can be increasingly disadvantageous as the number of analytes and/or the complexity of the sample matrix increases. Thus, hyphenation to a separation system prior to detection is desirable. Paper I appended to this thesis presents (for the first time) the on-line hyphenation between Fourier transform infrared spectroscopy, FTIR, and capillary zone electrophoresis, CZE. CZE is a highly efficient separation technique that separates ionic analytes with respect to their charge-to-size ratio. It is most commonly performed in aqueous buffers in fused silica capillaries. Since these capillaries absorb virtually all infrared light an IR-transparent flow cell had to be developed. In further studies (Paper II) the applicability of CZE is expanded to include neutral analytes by the addition of micelles to the buffer, and micellar electrokinetic chromatography, MEKC, was successfully hyphenated to FTIR for the first time. Paper III describes an application of the on-line CZE-FTIR technique in which non-UV-absorbing analytes in a complex matrix were separated, identified and quantified in one run.</p><p>Measuring aqueous solutions in the mid-IR region is not straightforward since water absorbs intensely in this region, sometimes completely, leaving no transmitted, detectable light. For this reason, quantum cascade lasers are interesting. These lasers represent a new type of mid-IR semiconducting lasers with high output power due to their ingenious design. The laser action lies within one conduction band (intersubband) and can be tailored to emit light in the entire mid-IR region using the same semiconducting material. To investigate their potential to increase the optical path length in aqueous solutions, these lasers were used with an aqueous flow system (Paper IV), and the experience gained in these experiments enabled hyphenation of such lasers to a CZE system (Paper V).</p>

on-line hyphenation

mid infrared detection

capillary electrophoresis

FTIR

quantum cascade laser

aqueous samples

Analytical chemistry

Analytisk kemi

Novel on-line mid infrared detection strategies in capillary electrophoretic systems

Kölhed, Malin

January 2005

Infrared absorption spectra can provide analytically useful information on a large variety of compounds, ranging from small ions to large biological molecules. In fact, all analytes that possess a dipole moment that changes during vibration are infrared-active. The infrared (IR) spectrum can be subdivided into far-, mid- and near- regions. The focus of attention in this thesis is the mid-IR region, in which the fundamental vibrations of most organic compounds are located, thus providing scope for positive structural identification. However, while such near-ubiquitous signals can be very useful for monitoring simple molecules in simple systems, they can be increasingly disadvantageous as the number of analytes and/or the complexity of the sample matrix increases. Thus, hyphenation to a separation system prior to detection is desirable. Paper I appended to this thesis presents (for the first time) the on-line hyphenation between Fourier transform infrared spectroscopy, FTIR, and capillary zone electrophoresis, CZE. CZE is a highly efficient separation technique that separates ionic analytes with respect to their charge-to-size ratio. It is most commonly performed in aqueous buffers in fused silica capillaries. Since these capillaries absorb virtually all infrared light an IR-transparent flow cell had to be developed. In further studies (Paper II) the applicability of CZE is expanded to include neutral analytes by the addition of micelles to the buffer, and micellar electrokinetic chromatography, MEKC, was successfully hyphenated to FTIR for the first time. Paper III describes an application of the on-line CZE-FTIR technique in which non-UV-absorbing analytes in a complex matrix were separated, identified and quantified in one run. Measuring aqueous solutions in the mid-IR region is not straightforward since water absorbs intensely in this region, sometimes completely, leaving no transmitted, detectable light. For this reason, quantum cascade lasers are interesting. These lasers represent a new type of mid-IR semiconducting lasers with high output power due to their ingenious design. The laser action lies within one conduction band (intersubband) and can be tailored to emit light in the entire mid-IR region using the same semiconducting material. To investigate their potential to increase the optical path length in aqueous solutions, these lasers were used with an aqueous flow system (Paper IV), and the experience gained in these experiments enabled hyphenation of such lasers to a CZE system (Paper V).

on-line hyphenation

mid infrared detection

capillary electrophoresis

FTIR

quantum cascade laser

aqueous samples

Analytical chemistry

Analytisk kemi

Optimization of Optical Nonlinearities in Quantum Cascade Lasers

Bai, Jing

19 July 2007

Nonlinearities in quantum cascade lasers (QCL¡¯s) have wide applications in wavelength tunability and ultra-short pulse generation. In this thesis, optical nonlinearities in InGaAs/AlInAs-based mid-infrared (MIR) QCL¡¯s with quadruple resonant levels are investigated. Design optimization for the second-harmonic generation (SHG) of the device is presented. Performance characteristics associated with the third-order nonlinearities are also analyzed. The design optimization for SHG efficiency is obtained utilizing techniques from supersymmetric quantum mechanics (SUSYQM) with both material-dependent effective mass and band nonparabolicity. Current flow and power output of the structure are analyzed by self-consistently solving rate equations for the carriers and photons. Nonunity pumping efficiency from one period of the QCL to the next is taken into account by including all relevant electron-electron (e-e) and longitudinal (LO) phonon scattering mechanisms between the injector/collector and active regions. Two-photon absorption processes are analyzed for the resonant cascading triple levels designed for enhancing SHG. Both sequential and simultaneous two-photon absorption processes are included in the rate-equation model. The current output characteristics for both the original and optimized structures are analyzed and compared. Stronger resonant tunneling in the optimized structure is manifested by enhanced negative differential resistance. Current-dependent linear optical output power is derived based on the steady-state photon populations in the active region. The second-harmonic (SH) power is derived from the Maxwell equations with the phase mismatch included. Due to stronger coupling between lasing levels, the optimized structure has both higher linear and nonlinear output powers. Phase mismatch effects are significant for both structures leading to a substantial reduction of the linear-to-nonlinear conversion efficiency. The optimized structure can be fabricated through digitally grading the submonolayer alloys by molecular beam epitaxy (MBE). In addition to the second-order nonlinearity, performance characteristics brought by the third-order nonlinearities are also discussed, which include third-harmonic generation (THG) and intensity dependent (Kerr) refractive index. Linear to third-harmonic (TH) conversion efficiency is evaluated based on the phase-mismatched condition. The enhanced self-mode-locking (SML) effect over a typical three-level laser is predicted, which will stimulate further investigations of pulse duration shortening by structures with multiple harmonic levels.

Quantum-cascade laser

Nonlinear optics

Supersymmetric quantum mechanics

Second-harmonic generation

Mid-infrared

intersubband transitions

Nonlinear optics

Lasers

Développement d'un spectromètre laser à cascade quantique pour des applications en spectroscopie de haute résolution et en métrologie des fréquences / Developpement of quantum cascade laser spectrometer for high resolution spectroscopy applications and frequency metrology

Sow, Papa lat tabara

23 April 2015

Ce travail de thèse porte sur le développement d'un spectromètre laser à cascade quantique (QCL) dans le moyen infrarouge pour des applications en spectroscopie et en métrologie des fréquences. Les principaux objectifs ont été tout d'abord de lever la forte contrainte que constitue le faible domaine spectral accessible au laser à CO2 mais également d'accroître la faible puissance laser disponible pour nos expériences de spectroscopie. Ce nouvel instrument intéresse directement les expériences développées au sein du groupe Métrologie Molécules et Tests Fondamentaux : la mise en évidence de non conservation de la parité dans les molécules chirales et la détermination de la constante de Boltzmann par spectroscopie laser. Au cours de ce travail de thèse, nous avons caractérisé le bruit d'intensité, le bruit de fréquence ainsi que la largeur de raie de la source QCL libre. Les résultats obtenus comparés à la littérature montrent une grande qualité spectrale de cette source laser. L'asservissement en phase de la source QCL sur un laser à CO2 ultra-stable a permis de démontrer le transfert des propriétés spectrales du laser à CO2 à la source QCL. Le spectromètre a ensuite été utilisé pour des expériences de spectroscopie en absorption linéaire des molécules NH3 et de la molécule de Méthyltrioxorhénium, molécules d'intérêt pour les projets de mesure de la constante de Boltzmann et de recherche d'un et de la non-conservation de la parité. Le potentiel de ce spectromètre a également été démontré dans des expériences de spectroscopie à très haute résolution, en absorption saturée. / This thesis is devoted to the developpement of a laser spectrometer quantum cascade to frequency metrology and high-resolution spectroscopy. The objective of this work is to developp a new tool for projects in our group : Measuring the Boltzman constant and test of non conservation of parity. Thus the new source was characterized by measuring its spectral density noise, amplitude noise and its emission line width. The phase locking of the QCL on the CO2 laser has achived spectroscopy NH and MTO, molecules of interest for the projects of the group mentioned aboive respectively.

Laser à cascade quantique

Accordabilité

Caractérisation spectrale

Asservissement

Puissance

Spéctroscopie de haute résolution

Quantum cascade laser

High resolution spectroscopy