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Návrh reverberátoru pro simulaci akustiky prostoru / Design of Reverberator for Room Acoustics SimulationHúserka, Jozef January 2014 (has links)
This thesis deals with artificial simulation of acoustic spaces by using reverberators. Output of this document consists of four reverberation algorithms and function that evaluates objective parameters of acoustic space from impulse responses. Reverberators and script were implemented using Matlab. Graphical user interface is used to present all of the algorithms for easier usability. First chapter deals with objective parameters of acoustic spaces and the ways they are computed from impulse response. Second chapter describes various structures which are used to build reverberators. Those structures are used in third chapter in implementations of reverberators. Third chapter also compares all implemented reverberators . In last chapter experiment was made. Impulse responses of three spaces were measured and subsequently aproximated by algorithms implemented in this thesis.
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LIGHT-MATTER INTERACTION FROM ATOMISTIC RARE-EARTH CENTERS IN SOLIDS TO MASSIVE LEVITATED OBJECTSXiaodong Jiang (10524008) 19 April 2022 (has links)
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<p>A harmonic oscillator is a ubiquitous tool in various disciplines of engineering and physics for sensing and energy transduction. The degrees of freedom, low noise oscillation, and efficient input-output coupling are important metrics when designing sensors and transducers using such oscillators. The ultimate examples of such oscillators are quantum mechanical oscillators coherently transducing information or energy. Atoms are oscillators whose degrees of freedom can be controlled and probed coherently by means of light. Elegant techniques developed during the last few decades have enabled us to use atoms, for example, to build exquisite quantum sensors such as clocks with the precision of <1 second error over the lifetime of the universe, to store and transduce information of various forms and also to develop quantum processors. Similar to atoms, mechanical oscillators can also be controlled ultimately to their single vibrational quanta and be used for similar sensing and transduction applications.</p>
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<p>In this thesis, we explore both atomic and mechanical systems and develop a toolbox to build an effective atom-light interface and light-oscillator interface for controlling such atomic and mechanical oscillators and use them in sensing and storage applications. Primarily, we study two disparate platforms: 1) rare-earth ions in solids integrated into photonic chips as a compact and heterogeneous platform and 2) nanoscopic and macroscopic oscillators interfaced with light and magnetic field to isolate them from environmental noise. </p>
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<p>Rare earth (RE) ions in crystals have been identified as robust optical centers and promising candidates for quantum communication and transduction applications. Lithium niobate (LN), a novel crystalline host of RE ions, is considered as a viable material for photonic system integration because of its electro-optic and integration capability. This thesis first experimentally reports the activation and characterization of LN crystals implanted with Yb and Er ions and describes their scalable integration with a silicon photonic chip with waveguide and resonator structures. The evanescent coupling of light emitted from Er ions with optical modes of waveguide and microcavity and modified photoluminescence (PL) of Er ions from the integrated on-chip Er:LN-Si-SiN photonic device with quality factor of 104 have been observed at room temperature. This integrated platform can ultimately enable developing quantum memory and provide a path to integrate more photonic components on a single chip for applications in quantum communication and transduction.</p>
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<p>Optomechanical systems are also considered as candidates for light storage and sensing. In this thesis, we also present results of the theoretical study of coherent light storage in an array of nanomechanical resonators. The majority of the thesis is focusing on an optomechanical sensing experiment based on levitation. An oscillator well isolated from environmental noise can be used to sense force, inertia, torque, and magnetic field with high sensitivity as the interaction with these quantities can change the amplitude or frequency of the oscillator’s vibration, which can be accurately measured by light. It has been proposed that such levitated macroscopic objects could be used as quantum sensors and transducers at their quantum ground states. They are also proposed as a platform to test fundamental physics such as detecting gravitational waves, observing macroscopic quantum entanglement, verifying the spontaneous collapse models, and searching for dark matter.</p>
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<p>In particular, we consider superconducting levitation of macroscopic objects in vacuum whose positions are measured by light. We build an optomechanical platform based on a levitated small high reflective (HR)-coated mirror above a superconductor disk. We use this levitated mirror at ambient conditions to detect the magnetic field with a sensitivity on the order of <em>pT/sqrt(Hz).</em> Moreover, the levitated mirror is used as the end mirror of a Fabry–Pérot cavity to create an optical resonance that could be used to study coherent radiation pressure forces. The platform provides a sensitive tool to measure the various forces exerted on the mirror and it offers the possibility of the coherent optical trapping of macroscopic objects and precision gravity sensing. Moreover, we study the nonlinear dissipation and mode coupling of a levitated HR-coated magnetic mirror above a superconducting disk in vacuum conditions. We observe that by exciting one vibrational mode of the mirror, the vibrational noise of another mode can be significantly suppressed by a factor of 60. We attribute this unique noise suppression mechanism to the mode coupling and nonlinear dissipation caused by the driven magnetic inhomogeneity of the levitated object. Such a suppression mechanism can enable cooling certain modes independent of their detection and position in the spectrum, which may be promising for precision sensing applications.</p>
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Ultracold Neutral Plasma Evolution in an External Magnetic FieldPak, Chanhyun 26 June 2023 (has links) (PDF)
We study the expansion velocity and ion temperature evolution of ultracold neutral plasmas (UNPs) of calcium atoms under the influence of a uniform magnetic field that ranges up to 200 G. In the experiments, we use a magneto-optical trap (MOT) to capture the neutral atoms and laser-induced fluorescence (LIF) to take images of the plasma. We vary the magnetic field strengths and the initial electron temperatures and observe the plasma evolution in time. We compare the ion temperature evolution to the theory introduced in the paper by Pohl et. al. [Phys. Rev. A 70, 033416 (2004)]. The evolution of the gradient of expansion velocity suggests the presence of ion acoustic waves (IAWs). We speculate that our measurements showing that the ion temperature remains relatively high throughout the evolution is a biproduct of the IAW.
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DEVELOPMENT OF FLUORESCENCE-DETECTED PHOTOTHERMAL MICROSCOPY METHODS FOR MAPPING CHEMICAL COMPOSITIONAleksandr Razumtcev (18097990) 04 March 2024 (has links)
<p dir="ltr">The beautiful complexity of our world is manifested in how macro- and even planetary-scale processes are essentially completely determined and regulated by chemical and physical transformations happening at the micro- and nanoscale. The introduction and subsequent development of optical microscopy methods have provided us with a unique opportunity to visualize, probe, and sometimes even control these processes that are too small to be seen by the human eye by their nature.</p><p dir="ltr">Among the great variety of truly impressive advances in microscopy instrumentation, two techniques stand out in their widespread and usefulness. First of them, fluorescence imaging has completely revolutionized the study of biological specimens and living systems due to its unprecedented single-molecule sensitivity and resolution combined with video-rate imaging capability. On the other hand, chemical imaging in the mid-infrared region provides an unmatched amount of chemical information enabling label-free mapping of the spatial distribution of various classes of biological molecules. However, each of these techniques falls short where the other excels. For example, despite its high resolution and sensitivity, fluorescence imaging does not carry direct chemical information and relies on labeling specificity, while infrared microscopy is diffraction-limited at the resolution of several micrometers and suffers from low penetration depth in aqueous solutions.</p><p dir="ltr">This dissertation introduces a novel imaging method designed to combine the advantages of fluorescence imaging and infrared spectroscopy. Fluorescence-detected photothermal mid-IR (F-PTIR) microscopy is presented in <b>chapter 1</b> as a technique enabling sub-diffraction chemically-specific microscopy by detecting local temperature-induced fluctuations in fluorescence intensity to inform on localized mid-infrared absorption. F-PTIR applications in targeted biological microspectroscopy (<b>chapter 1</b>) and pharmaceutical materials (<b>chapters 2 and 3</b>) analysis are demonstrated to highlight the potential of this new method. Furthermore, instrumentation developments relying on modern radiation sources such as dual-comb quantum cascade laser and synchrotron infrared radiation are shown to improve spectral acquisition speed (<b>chapter 4</b>) and spectral coverage (<b>chapter 5</b>), respectively, to extend the application range of F-PTIR.</p>
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Microcombs for Timekeeping and RF PhotonicsNathan Patrick O'Malley (17053956) 27 September 2023 (has links)
<p dir="ltr">Optical frequency combs have revolutionized metrology and advanced other fields such as RF photonics and astronomy. While powerful, they can be bulky, expensive, and difficult to manufacture. This tends to limit uses in real-world scenarios. Within the last decade or so, coherent frequency combs have begun to be generated in millimeter-scale, CMOS fabrication-compatible nonlinear crystals. These so-called “microcombs” have led to hopes of overcoming deployability constraints of more traditional bulk combs.</p><p dir="ltr">One of the first applications for \textit{bulk} frequency combs after their explosion in 2000 was the optical atomic clock. It promised extreme long-term time stability better than that of the Cesium clock that currently defines the SI second. More recently, interest in a fully portable optical atomic clock has grown. Such a device could reliably keep time even without the aid of GPS references, and potentially with greater accuracy than current GPS synchronization can provide.</p><p dir="ltr">Frequency combs have also been used to sample electrical signals more rapidly than traditional electronics can accomplish. This has been used to achieve dramatically increased effective frequency bandwidths for signal detection architectures. One can imagine how this capability would be beneficial in a portable (microcomb-driven) form: a lightweight, comb-enhanced receiver able to capture a broadband snapshot of its surrounding electromagnetic environment could be a powerful tool.</p><p dir="ltr">Timekeeping and RF photonics are the primary applications of microcombs focused upon here. I will attempt to roughly summarize important concepts and highlight relevant work in both subjects in the Introduction. Then I will move a step closer to the hands-on lab work that has largely kept me preoccupied over the last several years and describe important or commonly-employed Methods for experiments. A collection of three journal manuscripts (two published, and the third recently submitted) will follow in the Publications chapter, highlighting some experimental results. Finally, I will conclude with a brief Outlook.</p>
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Análisis y diseño de dispositivos pasivos de microondas y milimétricas en guía de ondas con excitación coaxialSan Blas Oltra, Ángel Antonio 24 May 2010 (has links)
Las guías coaxiales se emplean frecuentemente en la alimentación e interconexión de un elevado número de dispositivos de microondas y ondas milimétricas utilizados en numerosas aplicaciones prácticas (filtros, diplexores, multiplexores, etc.). Por ello, la caracterización rigurosa y eficiente de la excitación coaxial de dispositivos implementados en tecnología guiada es un tema de investigación muy importante que ha sido tratado ampliamente en la literatura técnica. Sin embargo, el número de contribuciones que se dedican a investigar este tema desde un punto de vista multimodal es realmente reducido.
El objetivo fundamental de este trabajo consiste en la caracterización multimodal eficiente de la excitación coaxial de dispositivos implementados en guía rectangular utilizando el método BI-RME (Boundary Integral - Resonant Mode Expansion) 3D. En concreto, en este trabajo se caracterizan dos tipos de configuraciones ampliamente utilizadas en la práctica: la excitación coaxial clásica, y la excitación coaxial en configuración colineal. Este último tipo de excitación se emplea comúnmente en los denominados filtros en configuración comb-line, los cuales también son objeto de investigación en el presente trabajo. En particular, se ha desarrollado una herramienta de análisis y diseño muy eficiente desde un punto de vista computacional que permite caracterizar de forma precisa este tipo de filtros.
Otro de los objetivos del presente trabajo es el análisis y el diseño de uniones en guía rectangular compensadas con postes conductores de geometría cilíndrica utilizando la técnica BI-RME 3D. Las uniones diseñadas (codos rectos, uniones en T, uniones T mágica y uniones turnstile) presentan una respuesta eléctrica óptima y, además, el trabajo desarrollado demuestra que la posición relativa del poste en la estructura es un parámetro de diseño muy importante que no se había considerado previamente en la literatura técnica dedicada a este tema. / San Blas Oltra, ÁA. (2008). Análisis y diseño de dispositivos pasivos de microondas y milimétricas en guía de ondas con excitación coaxial [Tesis doctoral]. Universitat Politècnica de València. https://doi.org/10.4995/Thesis/10251/8308
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Late Quaternary Plant Zonation and Climate in Southeastern UtahBetancourt, Julio L. January 1983 (has links)
Plant macrofossils from packrat middens in two southeastern Utah caves outline development of modern plant zonation from the late Wisconsin. Allen Canyon Cave (2195 m) and Fishmouth Cave (1585 m) are located along a continuous gradient of outcropping Navajo Sandstone that extends from the Abajo Mountains south to the San Juan River. By holding the site constant, changes in the floral composition for a plot of less than one hectare can be observed, even if sporadically, over tens of millennia. At Allen Canyon Cave, engelmann spruce-alpine fir forest was replaced by the present vegetation consisting of pinyon-juniper woodland on exposed ridgetops and cliffside stands of Douglas fir, ponderosa pine, and aspen. Xerophytic woodland plants such as pinyon, Plains prickly pear, and narrowleaf yucca arrived sometime in the middle Holocene between 7200 and 3400 B.P. At Fishmouth Cave, Utah juniper in Holocene middens replaced blue spruce, limber pine, Douglas fir, and dwarf and Rocky Mountain junipers in late Wisconsin samples. Disharmonious associations for the late Wisconsin occur only at the lower site with the xerophytes Mormon tea, Plains prickly pear, and narrowleaf yucca growing alongside subalpine conifers. One possible explanation involves the late Wisconsin absence of ponderosa and pinyon pines from the Colorado Plateaus. Released from competition at their lower limits, subalpine conifers were able to expand into lower elevations and mix with xerophytic plants found today in understories of pinyon-juniper and ponderosa pine woodlands. Quantitative climatic estimates are derived for the late Wisconsin by applying vertical lapse rates for temperature and precipitation to the amount of vegetation depression. The Fishmouth Cave sequence indicates a minimum lowering of 850 m for blue spruce, limber pine, and dwarf juniper. A depression of at least 700 m for engelmann spruce and alpine fir is suggested for the Allen Canyon locality. Use of conservatively low lapse rates for stations below 2080 m yields a 3-4°C cooling from present mean annual temperature and 35 to 60 percent more rainfall than today. Steeper lapse rates associated with more mountainous terrain suggest a 5°C lowering in temperature and up to 120 percent increase over modern precipitation.
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Toward an energy harvester for leadless pacemakers / Vers un récupérateur d'énergie pour stimulateur intracardiaqueDeterre, Martin 09 July 2013 (has links)
Ce travail consiste à développer un système convertissant une partie de l’énergie mécanique du cœur en électricité pour alimenter les stimulateurs cardiaques de nouvelle génération, implants sans sonde ni batteries implantés directement dans la cavité cardiaque. Après études de différentes sources d’énergies et concept associés, l’option liée à la pression sanguine, appliquant sur une partie souple du boîtier de l’implant des efforts transmis à un transducteur interne les convertissant en électricité, s’est révélée la plus prometteuse. Cette solution présente les avantages principaux suivants par rapport aux systèmes inertiels usuels : grande densité de puissance, adaptabilité au rythme cardiaque et potentiel de miniaturisation. Un boîtier ultra-souple électro-déposé de 10 µm d’épaisseur en forme de soufflet a été modélisé, fabriqué et caractérisé, validant ainsi le concept de récupérateur proposé. Un transducteur électrostatique novateur (3D multicouche à peignes interdigités et à chevauchement hors-plan), étudié par des modélisations analytiques et numériques, est en cours de fabrication. Selon l’électronique associée, ce transducteur promet une grande densité d’énergie extraite. Un transducteur piézoélectrique micro-usiné en forme de spirale et à électrodes micro-structurées, est également présenté. Les défis spécifiques des spirales dontla flexibilité permet d’augmenter l’énergie mécanique d’entrée sont étudiés notamment par simulation numériques, et des prototypes ont été micro-fabriqués et caractérisés. Au final, une énergie de 3 µJ/cm3/cycle est obtenue et de nombreuses perspectives d’amélioration permettent d’envisager une puissance au moins 10 fois supérieure. / This work consists in the development and design of an energy harvesting device to supply power to the new generation pacemakers, miniaturized leadless implants without battery placed directly in heart chambers. After analyzing different mechanical energy sources in the cardiac environment and associated energy harvesting mechanisms, a concept based on regular blood pressure variation stood out: an implant with a flexible packaging that transmits blood forces to an internal transducer. Advantages compared to traditional inertial scavengers are mainly: greater power density, adaptability to heartbeat frequency changes and miniaturization potential. Ultra-flexible 10-µm thin metal bellows have been designed, fabricated and tested. These prototypes acting as implant packaging that deforms under blood pressure actuation have validated the proposed harvesting concept. A new type of electrostatic transducer (3D multi-layer out-of-plane overlap structure with interdigitated combs) has been introduced and fully analyzed. Promising numerical results and associated fabrication processes are presented. Also, large stroke optimized piezoelectric spiral transducers including their complex electrodes patterns have been studied through a design analysis, numerical simulations, prototype fabrication and experimental testing. Apower density of 3 µJ/cm3/cycle has been experimentally achieved. With further addressed developments, the proposed device should provide enough energy to power autonomously and virtually perpetually the next generation of pacemakers.
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Μελέτη αποδέσμευσης ιόντων δισθενούς χαλκού από συμπολυμερή τύπου κτέναςΙατρίδη, Ζαχαρούλα 22 December 2009 (has links)
Διερευνήθηκε η δέσμευση/αποδέσμευση ιόντων Cu(II) ή/και αντίθετα φορτισμένων επιφανειοδραστικών ενώσεων από συμπολυμερή τύπου κτένας. Ο κεντρικός σκελετός ήταν το πολυ(ακρυλικό νάτριο), PANa, ενώ οι πλευρικές αλυσίδες ήταν το Πολυ(Ν,Ν-διμεθυλακρυλαμίδιο) και το πολυ(Ν-Ισοπροπυλακρυλαμίδιο). Η συμπλοκοποίηση των συμπολυμερών με τα ιόντα Cu(II)σε υδατικό περιβάλλον διερευνήθηκε με θολομετρία, ιξωδομετρία, φασματοφωτομετρία UV-Vis, δυναμική σκέδαση φωτός, ιχνηθέτηση με φθορίζοντες ιχνηθέτες και προσδιορισμό του ζ-δυναμικού. Σε επόμενο στάδιο διερευνήθηκε η δυνατότητα σχηματισμού τριμερών συμπλόκων ΡAΝa/Cu(II)/επιφανειοδραστικής ένωσης σε υδατικό περιβάλλον. Από τη φυσικοχημική μελέτη των συστημάτων σε συνάρτηση του pΗ, ελήφθησαν σημαντικές πληροφορίες σχετικά με τον ανταγωνισμό των δύο ειδών (ιόντα Cu(II)ή ιόντα επιφανειοδραστικής ένωσης) να σχηματίσουν σύμπλοκα με το PANa. Ως τελικό στάδιο, παρασκευάστηκαν αδιάλυτα στο νερό υβριδικά υλικά πολυμερούς/Cu(II)ή πολυμερούς/Cu(II)/επιφανειοδραστικής ένωσης. Έπειτα από διερεύνηση της συμβατότητας/αναμιξιμότητάς τους με εμπορικές μήτρες που χρησιμοποιούνται συνήθως στη βιομηχανία χρωμάτων, ορισμένα από αυτά ενσωματώθηκαν σε πραγματικά χρώματα. / The binding/release of Cu(II) ions or/and surfactants from comb-type copolymers was studied. The backbone was poly(sodium acrylate), PANa, whereas the side chains were poly(N, N-Dimethylacrylamide) and Poly9N-Isopropylacrylamide). The complexation of these copolymers with Cu(II) ions in water, was studied by turbidimetry, viscometry, UV-Vis fasmatophotometry, dynamic light scattering, fluorescense probing and ζ-potential. As a next step, the possible formation of ternary PANa/Cu(II)/surfactant complexes in water was studied. From the physiocochemical studies with pH, important information was taken as far as the competition of the two species (Cu(II) ions and surfactant) to form complexes with PANa is concerned. As a next step, water-insoluble hybrid polymer/Cu(II) or polymer/Cu(II)/surfactant materials were produced. After studies upon the compatibility/mischibility of the hybrid materials with matrices that are usually used in paints, some of the materials were incorporated to paints.
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Mélange à quatre ondes multiple pour le traitement tout-optique du signal dans les fibres optiques non linéaires / Multiple four wave mixing for all-optical signal processing in nonlinear optical fibersBaillot, Maxime 15 December 2017 (has links)
Le mélange à quatre ondes est un effet non linéaire sensible à la phase qui suscite de nombreux intérêts dans le domaine de la génération de peignes de fréquences et du traitement tout optique du signal par exemple. Un peigne de fréquences peut en effet s'obtenir par effet de mélange à quatre ondes 1en cascade. Dans ce cas, un nombre N d'ondes interagissent entre elles via l'effet Kerr et la modélisation d'un tel processus doit tenir compte de tous les couplages possibles entre les ondes. Au cours de mes travaux de thèse, je me suis intéressé, dans un premier temps, à la modélisation du mélange à quatre ondes dit multiple pour lequel un nombre quelconque N d'ondes interagissent entre elles. J'ai proposé une formulation générale permettant d'identifier simplement tous les termes de mélange à quatre ondes issus de toutes les combinaisons possibles de couplage entre les ondes et leur désaccord de phase associé. J'ai validé cette approche en proposant une étude théorique et expérimentale d'un processus de mélange à quatre ondes multiple dans une fibre optique non linéaire. Dans une deuxième partie, j'ai proposé, grâce au modèle élaboré précédemment, une étude théorique du phénomène de conversion de fréquence sensible à la phase, permettant la décomposition des composantes en quadrature d'un signal optique. Dans la littérature, cette expérience fut démontrée initialement avec quatre ondes pompes et dans plusieurs types de composants non linéaires. J'ai pu démontrer, au cours de mes travaux, que trois pompes étaient suffisantes pour réaliser l'expérience et j'ai déterminé des relations analytiques simples permettant de choisir les paramètres expérimentaux (notamment l'amplitude et la phase des pompes) rendant possible la décomposition des composantes en quadrature d'un signal. J'ai validé cette étude par la démonstration expérimentale d'un convertisseur de fréquence sensible à la phase avec uniquement trois pompes et j'ai étudié théoriquement les effets de la dispersion chromatique sur les performances du convertisseur de fréquence. Enfin, dans une dernière partie, j'ai caractérisé des fibres optiques microstructurées en verre de chalcogénure fabriquées dans le cadre d'une collaboration avec Perfos, l'Institut des Sciences Chimiques de Rennes et SelenOptics. Dans ce cadre, j'ai mis en place un banc de mesure de la dispersion chromatique et du coefficient non linéaire des fibres optiques basé sur le mélange à quatre ondes. / Four-wave mixing is a phase-sensitive nonlinear effect that arouses interest, particularly in the fields of frequency comb generation and all-optical signal processing. As an example, frequency combs can be produced thanks to a cascaded four-wave mixing process. In this case, N waves can interact with each other through the optical Kerr effect, and one has to take into account all the possible interactions to be able to adequately model the process. During my PhD thesis, I was interested in modeling the so-called multiple four-wave mixing process, in which any number N of waves can interact with each other. I proposed a general formulation that allows to easily identify all the four-wave mixing terms originating from all the possible combinations of wave coupling and their associated phase-mismatch terms. I validated this approach through the theoretical and experimental study of a multiple four-wave mixing process in a nonlinear optical fiber. Thanks to the developed model, I then proposed a theoretical study of the phase-sensitive frequency conversion process, which permits to demultiplex the quadrature components of an optical signal. In the literature, this process was first experimentally demonstrated in several nonlinear devices using four pump waves. I demonstrated that only three pump waves were required to successfully perform the experiment, and I determined the simple analytical relations from which the adequate experimental parameters (namely, the amplitudes and phases of the pump waves) could be deduced. I finally validated this study by experimentally demonstrating a phase-sensitive frequency conversion process with only three pump waves, and I theoretically studied the influence of chromatic dispersion on the performance of this frequency converter. Finally, I characterized some chalcogenide microstructured optical fibers that were fabricated in the framework of a collaboration with Perfos, the Institut des Sciences Chimiques de Rennes, and SelenOptics. I set up a test bench based on the four-wave mixing process in order to measure the chromatic dispersion and nonlinear coefficient of some optical fibers.
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