Global ETD Search

51	Power scaling of a hybrid microstructured Yb-doped fiber amplifier Mart, Cody, Pulford, Benjamin, Ward, Benjamin, Dajani, Iyad, Ehrenreich, Thomas, Anderson, Brian, Kieu, Khanh, Sanchez, Tony 22 February 2017 (has links) Hybrid microstructured fibers, utilizing both air holes and high index cladding structures, provide important advantages over conventional fiber including robust fundamental mode operation with large core diameters (>30 mu m) and spectral filtering (i.e. amplified spontaneous emission and Raman suppression). This work investigates the capabilities of a hybrid fiber designed to suppress stimulated Brillouin scattering (SBS) and modal instability (MI) by characterizing these effects in a counter-pumped amplifier configuration as well as interrogating SBS using a pump-probe Brillouin gain spectrum (BGS) diagnostic suite. The fiber has a 35 mu m annularly gain tailored core, the center doped with Yb and the second annulus comprised of un-doped fused silica, designed to optimize gain in the fundamental mode while limiting gain to higher order modes. A narrow-linewidth seed was amplified to an MI-limited 820 W, with near-diffraction-limited beam quality, an effective linewidth similar to 1 GHz, and a pump conversion efficiency of 78%. Via a BGS pump-probe measurement system a high resolution spectra and corresponding gain coefficient were obtained. The primary gain peak, corresponding to the Yb doped region of the core, occurred at 15.9 GHz and had a gain coefficient of 1.92x10(-11) m/W. A much weaker BGS response, due to the pure silica annulus, occurred at 16.3 GHz. This result demonstrates the feasibility of power scaling hybrid microstructured fiber amplifiers Photonic Bandgap Fiber Photonic Crystal Fiber Mode Instability Stimulated Brillouin Scattering
52	Raman Signal Enhancement and CARS Microscopy Naji, Majid January 2014 (has links) Raman biosensors are appealing for many biomedical applications, due to their accuracy and speed. In addition, Raman microscopy is a non-labeled imaging technique that offers chemical contrast based on Raman vibrational frequencies. However, the weak Raman signal represents a significant obstacle to using Raman in biological applications. The objective of my PhD research, presented in this thesis, is to enhance the Raman signal, thereby enabling it to be used in a wide variety of biomedical applications. More specifically, the research focuses on two different Raman signal enhancement techniques. The first is to improve the Raman signal using hollow-core photonic crystal fibers; this enhanced the Raman signal of ethanol 40 times. The second approach is by generating a coherent anti-Stokes Raman scattering (CARS) signal. We demonstrated CARS microscopy of myelin (lipid-rich) structures using a single femtosecond Ti:sapphire laser, and a photonic crystal fiber (PCF) with two closely lying zero dispersion wavelengths (ZDWs). Generating low noise supercontinuum (Stokes beam) out of two closely lying ZDW PCFs, enabled us to perform fast data acquisition (84 μs per pixel) CARS imaging using a homebuilt microscope. However, the application of this fiber is often limited to CARS imaging of molecular species with vibrations at wavenumbers ≥ 2000 cm−1 Raman shift. In addition, as it is not a polarization maintaining fiber, it cannot be used for polarization CARS microscopy. A polarization-maintaining PCF with two far-lying zero dispersion wavelengths offers important advantages for polarization CARS microscopy, and for CARS imaging in the fingerprint region. This PCF, though commercially available, has had limited use for CARS microscopy in the C-H bond region. The main problem is that the supercontinuum from this fiber is typically noisier than that from a standard PCF with two closely-lying zero dispersion wavelengths. To overcome this, we determined the optimum operating conditions for generating a low-noise supercontinuum out of a PCF with two far-lying zero dispersion wavelengths, in terms of the input parameters of the excitation pulse. We measured the relative intensity noise (RIN) of the Stokes and the corresponding CARS signal, as a function of the input laser parameters in this fiber. We demonstrated that the results of CARS imaging using this alternate fiber are comparable to those achieved using the standard fiber for input laser pulse conditions of low average power, narrow pulse width with a slightly positive chirp, and polarization direction parallel to the slow axis of the selected fiber. Finally, we demonstrated a novel fiber-delivered, portable, multimodal CARS exoscope, for minimally invasive in-vivo imaging of tissues. The device was based on a micro-electromechanical system-scanning mirror and miniaturized optics, and light delivery by photonic crystal fibre. A single Ti:sapphire femtosecond laser approach is used to produce CARS and two photon excitation fluorescent and second harmonic generation images of different samples using the new setup. The high resolution and distortion-free images achieved with various samples, particularly in the reverse direction (epi), successfully demonstrate proof of concept, and paves the way to minimally or non-invasive in vivo imaging. Moreover, combining this novel endoscope with a portable femtosecond fiber laser will accelerate delivering multimodal nonlinear imaging endoscopy/microscopy to clinical bed-side applications. Raman Spectroscopy CARS microscopy Supercontinuum generation Relative intensity noise Photonics crystal fiber
53	Mikrostrukturní optická vlákna s dutým jádrem / Hollow Core Photonic Crystal Fibers Hlavatý, Václav January 2015 (has links) Aim of the work was to study, design and verify methods of splicing photonic crystal fibers with standard single-mode and multi-mode fibers. The main goal was to make of the fusion splicer Fujikura FSM 100P splicing process. To create splicing process, various splicing methods were tested. Method of the moving position of the arc discharge from the center of splicing fibers and the method with increased gas pressure in the microstructure were mainly tested. Research revealed the incompatibility of splicing process of the different types of fiber splicers. The main results of the work are optimized methods of the splicing HC 1550-2 fiber and SMF 28 fiber.
54	Amplificateurs impulsionnels à base de fibres cristallines dopées Ytterbium / Ytterbium doped single crystal fiber amplifiers for ultra-short pulses Lesparre, Fabien 30 January 2017 (has links) Les lasers à impulsions ultra-courtes (< 10 ps) ont largement démontré leur intérêt pour de nombreuses applications scientifiques, industrielles ou encore médicales. Le domaine du micro-usinage par impulsions laser est l'un des domaines les plus actifs du moment. Les dernières avancées en la matière privilégient deux axes de recherche, l'augmentation du taux de répétition associé à de fortes puissances moyennes et une montée en énergie. Nos travaux s'inscrivent dans ce contexte et visent à développer des amplificateurs d'impulsions ultracourtes innovants à base de fibres cristallines Yb:YAG délivrant de fortes puissances moyennes et de fortes énergies en régime de polarisation cylindrique. Les sources développées sont destinées à être intégrées au sein de systèmes de micro-usinage laser aux performances inédites développés dans le cadre du projet européen Razipol. Celles-ci joueront le rôle de préamplificateur fort gain au sein d'une architecture MOPA composé d'un oscillateur ultra-rapide à base de cristal d'Yb:KYW et d'un amplificateur final à base de disque mince Yb:YAG. Pour répondre à la problématique des dégradations spatiales liées à la montée en puissance moyenne dans les architectures à laser solide pompé par diode, une architecture en cascade composée de trois étages d'amplification permettant de réduire la charge thermique a d'abord été réalisée. Grâce à une fine optimisation de l’ensemble des paramètres spectroscopiques (taux de dopage des cristaux, longueur d'onde de pompe...) et géométriques (longueur des cristaux, tailles de faisceaux...) a permis d'amplifier des impulsions femtosecondes (750 fs) jusqu'à des puissances moyennes de 100 et 85 W, respectivement obtenues en polarisation linéaire et cylindrique, à la cadence de 20 MHz. Un amplificateur picoseconde de forte énergie à également été réalisé. Intégrant un dispositif de combinaison cohérente à division temporelle à 4 ou 8 répliques visant à réduire les effets non-linéaires, la source développée délivre des énergies remarquablement élevées pour ce type de système à amplification directe. Il délivre des énergies de 1 et 2 mJ à des cadences inférieures à 20 kHz. Ces résultats ont fait l'objet de 2 publications dans des revues internationales à comité de lecture. Par ailleurs les deux amplificateurs développés ont été intégrés sous la forme de systèmes compactes et robustes, utilisables par les membres du projet européen Razipol. Ces travaux ont également inspirée une nouvelle ligne de produits désormais commercialisés la société Fibercryst. / In the last decade ultra-short pulse laser (< 10 ps) have sparked increasing interest for many industrial and scientific applications. Among the geometries used so far for high-power Yb-doped diode-pumped solid-state lasers as slabs, rods and thin disks, the single crystal fiber (SCF) technology was recently shown to have a high potential for the amplification of ultrashort pulses thanks to a very efficient thermal management and high optical efficiencies. This technology combined with the cubic crystal structure of Yb:YAG offers a cylindrical symmetry of the optical and thermo-mechanical properties. Yb:YAG SCFs are therefore well suited for the amplification of cylindrically polarized beams. In the context of a European Project called RAZIPOL, we have developed new laser amplifier architectures using SCF to directly amplify femtosecond pulses to achieve high energy and high average power pulses with radial and azimuthal polarizations without any stretching and recompression of the pulses.We first demonstrate a three-stage diode-pumped Yb:YAG single-crystal-fiber amplifier to generate femtosecond pulses at high average powers with linear or cylindrical (i.e., radial or azimuthal) polarization. At a repetition rate of 20 MHz, 750 fs pulses were obtained at an average power of 85 W in cylindrical polarization and at 100 W in linear polarization. Investigations on the use of Yb:YAG single-crystal fibers with different length/doping ratios and the zero-phonon pumping at a wavelength of 969 nm were conducted in order to optimize the performances of the amplifiers.The second part of the project is focused on pulse energy scaling. In this sense, we demonstrate a two-stage Yb:YAG single-crystal-fiber amplifier designed for high peak power to significantly increase the pulse energy of a low power picosecond laser. The first amplifier stage has been designed for high gain. Using a gain medium optimized in terms of doping concentration and length an optical gain of 32dB has been demonstrated. The second amplifier stage designed for high energy using divided pulse technique allows to generate recombined output pulse energy of 2mJ at 12.5 kHz with a pulse duration of 6 ps corresponding to a peak power 320MW. Average powers ranging from 25W to 55W with repetition rates varying from 12.5 kHz to 500 kHz have been demonstrated.This results has led to the publication of 2 articles in international peer-reviewed journals and have been presented in 7 conferences. Finally this work has inspired the launch of a new line of industrial products by Fibercryst. Laser Ytterbium Amplificateur Fibre cristalline Impulsions Laser Ytterbium Amplifier Single-Crystal fiber Pulse 535.5
55	Peak Power Scaling Of Nanosecond Pulses In Thulium Based Fiber Lasers Gaida, Christian 01 January 2013 (has links) Thulium based fiber lasers represent a promising alternative for pulse energy scaling and high peak power generation with ytterbium based systems at 1µm. Advantages of thulium arise from the operation at longer wavelengths and a large gain bandwidth (1.8-2.1µm). Nonlinear effects, such as self phase modulation, stimulated Raman scattering and stimulated Brillouin scattering generally limit peak power scaling in fiber lasers. The longer wavelength of thulium fiber lasers and large mode field areas can significantly increase the nonlinear thresholds. Compared to 1µm systems, thulium fiber lasers enable single mode guidance for two times larger mode field diameter in step index fibers. Similar behavior is expected for index guiding thulium doped photonic crystal fibers. In this work a novel thulium doped rod type photonic crystal fiber design with large mode field diameter ( > 50µm) was first characterized in CW-lasing configuration and then utilized as final amplifier in a two stage master oscillator power amplifier. The system generated MW-level peak power at 6.5ns pulse duration and 1kHz repetition rate. This world record performance exemplifies the potential of thulium fiber lasers to supersede ytterbium based systems for very high peak power generation in the future. As part of this work a computer model for the transient simulation of pulsed amplification in thulium based fiber lasers was developed. The simulations are in good agreement with the experimental results. The computer model can be used for efficient optimization of future thulium based fiber amplifier designs. Fiber laser fiber amplifier photonic crystal fiber master oscillator power amplifier thulium Electromagnetics and Photonics Optics
56	Photonic Crystal Fibers and Optical True Time Delay Engines for Wideband Arrays Nahar, Niru Kamrun 08 September 2008 (has links) No description available. Electrical Engineering Optics Photonic crystal fiber Free-space coupling White cell beam steering
57	Using saturated absorption spectroscopy on acetylene-filled hollow-core fibers for absolute frequency measurements Knabe, Kevin January 1900 (has links) Doctor of Philosophy / Department of Physics / Kristan L. Corwin / Current portable near-infrared optical frequency references offer modest accuracy and instability compared to laboratory references. Low pressure reference cells are necessary to realize features narrower than the Doppler broadened overtone transitions, and most setups to date have occurred in free-space. Hollow-core photonic crystal fibers offer a potential alternative to free-space setups through their small cores (~10’s of µm) and low-loss guidance. Furthermore, HC-PCF can be made into fiber cells that could be directly integrated into existing telecommunications networks. Efforts were made to fabricate these fiber cells with a low pressure of molecules trapped inside, but this has proven to be quite challenging. Therefore, investigation of these fibers is conducted by placing the ends of the fiber inside vacuum chambers loaded with acetylene (12C2H2). The linewidths of several P branch transitions (near 1.5 µm) are investigated as a function of acetylene pressure and optical pump power in three different HC-PCFs. Frequency modulation spectroscopy is then implemented on the acetylene-filled HC-PCF to generate sub-Doppler dispersion features that are useful for frequency stabilization using standard servo electronics. Instability and accuracy of this near-IR optical reference were then determined by analysis of heterodyne experiments conducted with frequency combs referenced to a GPS-disciplined rubidium oscillator. The instability and accuracy of this HC-PCF reference are within an order of magnitude of free-space experiments, as expected based on the ratio of linewidths observed in the two experiments. Therefore, HC-PCF has been shown to be suitable for potential frequency references. Further work is necessary to fabricate gas fiber cells with high optical transmission and low molecular contamination. Hollow core photonic crystal fiber Physics, Atomic (0748) Physics, Molecular (0609) Physics, Optics (0752)
58	Implementação da técnica de varredura-Z com luz branca supercontínua gerada em fibras fotônicas na determinação do espectro de não linearidades / Implementation of Z-Scan technique with white light continuum generated in a photonic crystal fiber for nonlinear spectrum determination Siqueira, Jonathas de Paula 22 February 2008 (has links) Nesta dissertação, propomos um método que combina a técnica de varredura-Z e a luz branca supercontínua gerada em uma fibra fotônica para caracterizar o espectro de não-linearidades de amostras. O espectro não-linear fornece informações cruciais a respeito da característica, da origem e do potencial da não-linearidade para aplicação em dispositivos. Neste sentido, a luz branca supercontínua aliada à técnica de varredura-Z vem permitir uma rápida determinação de espectros numa banda larga. Neste trabalho, a luz branca foi gerada numa fibra fotônica comercial bombeada por pulsos de femtossegundo de um oscilador laser de Ti:safira. Tanto os lasers de femtosegundo quanto as fibras fotônicas estão se tornando cada vez mais acessíveis. Ademais, a técnica de varredura-Z é um método bastante conhecido para a determinação de não-linearidades devido à sua simplicidade e precisão. Dessa forma, aliamos essas vantagens para fazer um aparato simples, compacto e de baixo custo. Em geral, a determinação do espectro de não-linearidades necessita de sistemas lasers complexos que possam sintonizar o comprimento de onda. O método de varredura-Z de luz branca desenvolvido aqui foi usado para medir o espectro não-linear do corante disperse red 13 (DR13) em metanol. Esse corante possui um efeito não-linear absortivo (absorção saturada) bem caracterizado, sendo um bom material não apenas para calibração, mas também para testar nosso sistema experimental. Os resultados experimentais comprovaram a viabilidade do sistema para caracterização de amostras com efeitos não-lineares absortivos intensos. / In this dissertation, we proposed a method that combines the Z-scan technique and the white-light continuum generated by a photonic crystal fiber to characterize the nonlinear spectrum of materials. The nonlinear spectrum provides crucial information on the characteristic, the origin and the potential of the nonlinearity for devices application. In this sense, the white-light continuum allied to the Z-scan technique allows fast spectra determination in a broad spectral range. In this work, the white light was generated in a commercial photonic crystal fiber pumped by femtosecond pulses from a Ti:sapphire laser oscillator. Both the femtosecond lasers and the photonic crystal fibers are becoming more accessible. In addition, the Z-scan technique is a well-known method for nonlinearities determination due to its simplicity and precision. In this way, we merged these advantages to make a simple, compact and low-cost apparatus for studying nonlinear samples. In general, the nonlinear spectrum determination requires complex laser systems which are able to tune the wavelength. The white-light Z-scan method we developed here was used to measure the nonlinear spectrum of disperse red 13 (DR13) dye in methanol. This dye presents a well-characterized absorcive nonlinear effect (saturable absorption), being a good material not only to calibrate, but also to test our experimental setup. The experimental results confirmed the viability of the setup for characterizing samples with strong nonlinear absorption effect. Absorção saturada Fibra fotônica Luz branca supercontínua Photonic-crystal fiber Saturated absorption Varredura-Z White-light continuum Z-scan
59	Proposição e estudo de fibras ópticas microestruturadas tipo D: gerenciamento de dispersão e alta birrefringência / Proposal and study of microstructured optical fiber D-type: dispersion management and high birefringence Spadoti, Danilo Henrique 02 October 2008 (has links) Este trabalho de doutoramento propôs investigar novas configurações geométricas para as fibras ópticas microestruturadas a base de sílica. Aproveitando-se da flexibilidade que sua geometria proporciona, diferentes das fibras ópticas convencionais, foram propostas fibras ópticas microestruturadas com perfil tipo D atuando, especificamente, em duas aplicações distintas: fibras compensadoras de dispersão ou fibras altamente birrefringentes. Para o estudo teórico das fibras ópticas microestruturadas foram utilizados dois métodos numéricos: o método da Sobre-Relaxação Sucessiva (SOR) e o método de Arnoldi Implicitamente Reiniciado (IRAM). Foi necessário implementar o método IRAM para determinar os modos de mais alta ordem presentes em guias de onda multimodos, uma vez que o método SOR fornece apenas a solução para o modo fundamental. Neste contexto, as fibras ópticas microestruturadas com perfil D, propostas e investigadas neste trabalho, demonstraram ser extremamente promissoras para atuar na compensação da dispersão cromática ou no aumento do efeito da birrefringência. Foram projetadas fibras capazes de compensar a dispersão em banda larga, cobrindo as bandas de telecomunicações S, C e L, ou, ainda, fibras com um alto coeficiente de dispersão negativo em torno do comprimento de onda de 1550nm. Adicionalmente, verificou-se também que com as novas configurações propostas foi possível projetar fibras com elevado grau de birrefringência, sendo atrativas no projeto de fibras mantedoras do estado de polarização. / This work proposed to investigate new geometric configurations for the silica microstructured optical fibers. Based on their design flexibility, not usually found in conventional silica fibers, D-shape microstructured optical fibers were designed, specifically, for two different applications: dispersion compensation or high birefringence. For the theoretical analysis two numerical methods were used: the finite difference Successive Over Relaxation (SOR) method, and the Implicitly Restarted Arnoldi Method (IRAM). It was necessary to develop the IRAM method to determine the higher order modes inside the multimodo optical waveguide, since the SOR method is able to yield only the fundamental mode. In this framework, the D-shape microstructured optical fibers, which have been proposed and investigated in this work, proved to be extremely efficient for chromatic dispersion compensation and increasing the birefringent effect. Fibers have been designed in order to compensate the wideband dispersion, covering three entire telecommunication bands, namely: S-, C- and L- bands, simultaneously. Additionally, with these new proposed configurations it is possible to design high birefringent fibers, which are very attractive in polarization maintaining applications. Birefringence Birrefringência Compensação de dispersão Dispersion compensation Fibra de cristal fotônico Fibra óptica microestruturada Microstructured optical fiber Photonic crystal fiber
60	Segregation effects in single-crystal fibers grown by the micro-pulling-down method Maier, Dirk 11 August 2009 (has links) In dieser Arbeit wurden Segregationen, die bei der Z"uchtung einkristalliner Fasern von Oxidmischkristallsystemen mittels der Micro-Pulling-Down Methode auftreten, experimentell und theoretisch untersucht. Dazu wurden Fasern von hochschmelzenden Oxidmischkristallsystemen mit unterschiedlichen Gleichgewichtsverteilungskoeffizienten gezüchtet. Es wurde gezeigt, dass die Dotierstoffprofil von dem Gleichgewichtsverteilungskoeffizienten, der Ziehgeschwindigkeit, dem Sauerstoffpartialdruck der Züchtungsatmosphäre sowie der Meniskushöhe abhängt. Ein analytisches und ein numerisches Modell wurden erstellt um den Segregationsprozess zu beschreiben. Ein Modell basierend auf der irreversiblen Thermodynamik wurde zur Berechnung der Thermodiffusionskoeffizienten mittels Enthalpie und Entropie hergeleitet. Ausserdem wurden mechanische Spannungen, die durch die Segregationen erzeugt werden, untersucht. LiYF4 wurde erfolgreich gezüchtet. Für diesen Fall wurde die Notwendigkeit einer reinen Züchtungsatmosphäre sowie eines reinen Ausgangsmaterials in Bezug auf Wasser- und Sauerstoffverunreinigungen, gezeigt. / Within this study segregations, which occur during micro-pulling-down growth of single-crystal fibers of oxide solid solutions, have been analyzed in an experimental and theoretical manner. Single-crystal fibers of high melting point oxide solid solutions with different equilibrium distribution coefficient have been grown. It has been shown, that the dopant distribution depends on the equilibrium distribution coefficient of the dopant, the pulling speed, the oxygen partial pressure of the growth atmosphere and the meniscus height. An analytical and a numerical model have been established to describe the segregation process. A theoretical model based on irreversible thermodynamics to calculate the thermodiffusion factors using the enthalpy and entropy was derived. Also mechanical stresses induced by the segregation have been analyzed. LiYF4 has been grown successfully. In this case the necessity of a very high purity atmosphere and source material in terms of water and oxygen trace impurities has been shown. Segregation Oxide Kristallzüchtung Einkristallfasern Crystal growth Segregation Single-crystal fiber Oxides 530 Physik 29 Physik, Astronomie ddc:530

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