Global ETD Search

81	Development of a Compact Broadband Optical Parametric Oscillator for Ultra-Sensitive Molecular Detection Crystal, Sean O 01 January 2017 (has links) Every gas molecule has a unique absorption spectrum that can be captured using optical spectroscopy to identify an unknown sample's composition. Frequency combs systems can provide an extremely broad mid-infrared spectrum that is very useful for molecular detection. A degenerate optical parametric oscillator (OPO) was built to generate the down-converted and shifted frequency comb spectrum. This system utilizes an ultra-short pulse 1.56µm pump laser and a never before used orientation patterned gallium-phosphide crystal. Periodically polled lithium niobate (PPLN), Gallium Arsenide (GaAs) and Gallium Phosphide are all crystals used to accomplish this task. GaP, in comparison to PPLN, has (i) a larger nonlinear coefficient, (ii) much deeper infrared transparency, and (iii) smaller group dispersion – to allow for achieving broad spectral coverage. GaP also has a larger band gap than GaAs; therefore it can still be pumped with a standard telecom C-band laser. An octave-wide spanning frequency comb system was achieved and the characterization of the system is presented. This system is specifically designed to be compact and portable for initial experimental testing in the applications of medical breath analysis and combustion gas investigation. Optical Parametric Oscillator Frequency Comb Molecular Detection Laser Atomic, Molecular and Optical Physics Optics
82	Free-space NPR mode locked erbrium doped fiber laser based frequency comb for optical frequency measurement Turghun, Matniyaz January 1900 (has links) Master of Science / Department of Physics / Brian R. Washburn / This thesis reports our attempt towards achieving a phase stabilized free-space nonlinear polarization rotation (NPR) mode locked erbium doped fiber laser frequency comb system. Optical frequency combs generated by mode-locked femtosecond fiber lasers are vital tools for ultra-precision frequency metrology and molecular spectroscopy. However, the comb bandwidth and average output power become the two main limiting elements in the application of femtosecond optical frequency combs. We have specifically investigated the free-space mode locking dynamics of erbium-doped fiber (EDF) mode-locked ultrafast lasers via nonlinear polarization rotation (NPR) in the normal dispersion regime. To do so, we built a passively mode-locked fiber laser based on NPR with a repetition rate of 89 MHz producing an octave-spanning spectrum due to supercontinuum (SC) generation in highly nonlinear fiber (HNLF). Most significantly, we have achieved highly stable self-starting NPR mode-locked femtosecond fiber laser based frequency comb which has been running mode locked for the past one year without any need to redo the mode locking. By using the free-space NPR comb scheme, we have not only shortened the cavity length, but also have obtained 5 to 10 times higher output power (more than 30 mW at central wavelength of 1570 nm) and much broader spectral comb bandwidth (about 54 nm) compared to conventional all-fiber cavity structure with less than 1 mW average output power and only 10 nm spectral bandwidth. The pulse output from the NPR comb is amplified through a 1 m long EDF, then compressed by a length of anomalous dispersion fiber to a near transform limited pulse duration. The amplified transform limited pulse, with an average power of 180 mW and pulse duration of 70 fs, is used to generate a supercontinuum of 140 mW. SC generation via propagation in HNLF is optimized for specific polling period and heating temperature of PPLN crystal for SHG around 1030 nm. At last, we will also discuss the attempt of second harmonic generation (SHG) by quasi phase matching in the periodically polled lithium niobate (PPLN) crystal due to nonlinear effect corresponding to different polling period and heating temperature. Mode-locked laser Frequency comb Erbium doped fiber laser Nonlinear polarization rotation Phase stabilization Ultra-short pulse Engineering (0537) Optics (0752) Physics (0605)
83	Electro-Optic Phase Modulation, Frequency Comb Generation, Nonlinear Spectral Broadening, and Applications Oscar E Sandoval (6887678) 15 August 2019 (has links) <p>Electro-optic phase modulation can be used to generate high repetition rate optical frequency combs. The optical frequency comb (OFC) has garnered much attention upon its inception, acting as a crucial component in applications ranging from metrology and spectroscopy, to optical communications. Electro-optic frequency combs (EO combs) can be generated by concatenating an intensity modulator and phase modulator together. The first part of this work focuses on broadening the modest bandwidth inherent to the EO combs. This is achieved by propagation in a nonlinear medium, specifically propagation in a nonlinear optical loop mirror (NOLM). This allows for broadening the EO frequency comb spectrum to a bandwidth of 40 nm with a spectral power variation of < 10 dB. This spectrally broadened EO comb is then used in dual comb interferometry measurements to characterize the single soliton generated in an anomalous dispersion silicone-nitride microresonator. This measurement allows for rapid characterization with low average power. Finally, electro-optic phase modulation is used in a technique to prove frequency-bin entanglement. A quantum network based on optical fiber will require the ability to perform phase modulation independent of photon polarization due to propagation in optical fiber scrambling the polarization of input light. Commercially available phase modulators are inherently dependent on the polarization state of input light making them unsuited to be used in such a depolarized environment. This limitation is overcome by implementing a polarization diversity scheme to measure frequency-bin entanglement for arbitrary orientations of co- and cross- polarized frequency-bin entangled photon pairs.</p> electro-optics eelctro-optic phase modulation electro-optic frequency combs dual comb interferometry frequency-bin entanglement
84	Optical parametric oscillators for precision IR spectroscopy and metrology Kovalchuk, Evgeny 21 May 2008 (has links) In der vorliegenden Doktorarbeit wird ein Dauerstrich Optisch Parametrischer Oszillator (cw OPO) vorgestellt, der speziell für die hochauflösende Dopplerfreie Molekülspektroskopie und Metrologie entwickelt wurde. Der kontrollierte Zugang zu jeder beliebigen Wellenlänge im breiten Emissionsspektrum von OPOs wie auch das präzise Abstimmen seiner Ausgangsfrequenz über zu untersuchende molekulare und atomare Übergänge stellten lange Zeit Probleme dar, deren Lösung die Grundzielsetzung dieser Arbeit war. Das im Laufe dieser Arbeit entwickelte System hat diese Ziele vollständig erreicht, was durch verschiedene Messungen und Anwendungen demonstriert wurde. Zu diesem Zweck wurde ein neues OPO-Design mit einem Intracavity-Etalon entwickelt und aufgebaut, wobei der OPO auf dem Konzept eines einfach-resonanten cw OPOs mit resonanter Pumpwelle basiert. Die OPO-Ausgangsstrahlung zeigt sehr gute Langzeitstabilität und Spektraleigenschaften, welche durch direkte Frequenzvergleichsmessungen mit einem optischen Methan-Frequenzstandard im Infraroten bestimmt wurden. Eine Idler-Linienbreite von 12 kHz und ein Modensprung-freier Betrieb des OPOs über einen Zeitraum von einigen Tagen wurde beobachtet. Außerdem wurde gezeigt, dass ein OPO zu einer hochstabilen optischen Referenz phasengelockt und somit seine Frequenz sehr genau kontrolliert und durchgestimmt werden kann. Als erste erfolgreiche Anwendung eines OPOs in der Dopplerfreien Spektroskopie wurde ein Aufbau zur Frequenz-Modulationsspektroskopie in Methan realisiert. Weiterhin, wurde der entwickelte cw OPO mit einem femtosekunden optischen Frequenzkamm kombiniert, um eine neue Idee für eine kohärente Verbindung zwischen dem sichtbaren und dem infraroten Spektralbereich zu realisieren. Als erste Demonstration dieser Technologie wurde ein direkter absoluter Frequenzvergleich zwischen einem Jod-stabilisierten Laser bei 532 nm und einem Methan-stabilisierten Laser bei 3390 nm durchgeführt. / This thesis presents a continuous-wave optical parametric oscillator (cw OPO), specially developed for high-resolution Doppler-free molecular spectroscopy and metrology. The basic objective was to solve the long-standing problem of controlled access to any desired wavelength in the wide emission range of OPOs, including the ability to precisely tune the output frequency over the molecular and atomic transitions of interest. The system implemented during this work fully achieves these goals and its performance was demonstrated in various measurements and applications. For this aim, a new design for the OPO cavity with an intracavity etalon was implemented, extending the concept of a cw singly resonant OPO with resonated pump wave. The newly developed device demonstrates very good long-term stability and spectral properties, which were determined in direct beat frequency measurements with a methane infrared optical frequency standard. Thus, an idler radiation linewidth of 12 kHz and mode-hop-free operation of the OPO over several days were observed. Furthermore, it was shown that an OPO can be phase locked to a highly stable optical reference and thus much more precisely controlled and tuned. As the first successful application of OPOs in Doppler-free spectroscopy, a frequency modulation spectroscopy setup for detection of sub-Doppler resonances in methane was implemented. Furthermore, the developed cw OPO was integrated with a femtosecond optical frequency comb to realize a new concept for a coherent link between the visible and infrared spectral ranges. As a first demonstration of this technique, a direct absolute frequency comparison between an iodine stabilized laser at 532 nm and a methane stabilized laser at 3390 nm was performed. Metrologie Optisch Parametrischer Oszillator Präzisionsexperimente metrology optical parametric oscillator precision experiments 530 Physik 29 Physik, Astronomie ddc:530
85	Interférométrie avec des lasers femtosecondes infrarouges / Femtosecond infrared lasers interferometry Jacquet, Patrick 26 January 2011 (has links) En plus de 40 ans d’existence, la spectroscopie de Fourier, basée sur l’interféromètre de Michelson,a permis des progrès considérables dans notre connaissance de la structure des atomes et des molécules s’imposant peu à peu comme un outil de base pour le diagnostic optique. Aujourd’hui, dépasser ses performances en terme de limite de résolution, rapidité, sensibilité et exactitude permettrait de répondre à de nouveaux enjeux. Cette thèse porte sur le développement expérimental de la spectroscopie de Fourier par peignes de fréquences femtosecondes. Deux peignes de fréquences, lasers composés de centaines de milliers de raies fines dont la position est parfaitement contrôlée, sondent l’échantillon et la transformation de Fourier de leurs interférences temporelles fournit le spectre. Trois dispositifs basés sur des lasers femtosecondes à fibres dopées (à 1 μm et 1.5 μm) ou à solides (à 2.4 μm) illustrent les performances de la méthode. Par comparaison à la spectroscopie de Fourier traditionnelle, les temps de mesure ont été réduits de la seconde à la microseconde, pour des spectres de molécules en phase gazeuse couvrant une centaine de nanomètres à des limites de résolution du GHz. La sensibilité atteint celle des spectromètres par laser accordable les plus performants grâce à des méthodes de détection différentielle ou d’utilisation de cavités multipassages ou résonnantes. Augmenter le temps de mesure et résoudre les raies individuelles du peigne permet une spectroscopie de précision à large bande spectrale, car la fréquence absolue de chaque raie de peigne peut être connue avec l’exactitude d’une horloge atomique. / For four decades, Fourier transform spectroscopy has greatly improved our atomes and molecules structures knowledges, and thus became a widely used tool for optical diagnosis. However, today it is useful to overcome some of its limitations in order to address new challenges. This thesis is about experimental developpement concerning frequency comb fourier transform spectroscopy. Two frequency combs, made of thousands of very narrow frequency lines perfectly known and controlled, are probing an absorbing sample. The fourier transform of their temporal interference pattern provides the optical spectrum. Three devices based on fiber doped lasers (emitting at 1μm and 1.5 μm) and solid lasers (at 2.4 μm) are used to demonstrate the method advantages. Compared to traditional Fourier transform spectroscopy the recording time has shrunk by one million for the acquisition of spectra spreading on a hundred of nanometers at GHz resolution. Using multipass cells of differential detection devices, the sensitivity reached is comparable to that provided by the most efficient laser based methods. Increasing the resolution allows for clear observation of the comb individual tooth which position can be measured with the accuracy of an atomic clock, providing thus a simple and accurate method for auto calibrated spectra. Spectroscopie de Fourier Laser femtoseconde infrarouge Peigne de fréquences femtose- conde Spectroscopie de Fourier à deux peignes Fourier transform spectroscopy Femtosecond frequency combs Dual-comb spectroscopy Multi-heterodyne spectroscopy
86	Mesure de distance absolue utilisant l'interférométrie à balayage de longueur d'onde étalonnée par un peigne de fréquences / Absolute distance measurement using frequency sweeping interferometry calibrated by frequency comb Yu, Wenhui 10 April 2019 (has links) Dans cette thèse, nous avons mis en oeuvre un système de mesure de distance absolue (Absolute Distance Measurement, ADM) de haute précision utilisant l'interférométrie à balayage de fréquence (Frequency Sweeping Interferometry, FSI). La technique FSI exige que la plage de réglage de fréquence du laser balayé soit mesurée avec une précision élevée, ce qui est difficile en raison de l'absence d'un moyen simple de mesurer la haute fréquence d'un laser en temps réel. Dans cette thèse, un peigne de fréquence a été utilisé comme règle de fréquence lumière pour mesurer la plage de réglage de la fréquence du laser à balayage. Un peigne de fréquence formé par un laser femtoseconde est constitué de millions de lignes de peigne régulièrement espacées, ce qui permet de le considérer comme une règle de fréquence de la lumière. La calibration de fréquence a été réalisée en filtrant le signal hétérodyne entre le laser à balayage et les lignes de peigne en utilisant un filtre passe-bande étroit. Cette approche nous permet de détecter le signal d'étalonnage lorsque la fréquence du laser à balayage est proche d'une ligne en peigne. Etant donné que l’intervalle de fréquence entre les lignes de peigne peut être mesuré avec précision ou activement verrouillé en phase par rapport à un oscillateur radiofréquence (RF) stable, la plage d ’ accord du laser à balayage peut être mesurée avec une grande précision. En particulier, chacun des deux pics d’étalonnage peut être utilisé dans le calcul de la distance, ce que nous appelons des «sous-mesures» en un seul balayage. Combinée au grand nombre de lignes de peigne, la moyenne des sous-mesures améliore considérablement la précision des mesures sans balayage multiple. Dans la thèse, la condition de détection et les caractéristiques du signal hétérodyne entre le laser à balayage et la ligne de peigne sont présentées. Une conception de filtre pour filtrer le signal hétérodyne est réalisée. Un travail de modélisation concernant l'effet du bruit de phase des lasers sur la distorsion d'enveloppe du pic d'étalonnage a été présenté. Des travaux expérimentaux basés sur les concepts de mesure ont été réalisés. Il montre que l'utilisation du schéma de mesure proposé peut considérablement améliorer la précision de la mesure de distance. Dans l’une des mesures, une précision de 30 nm pour une distance d’environ 0,8 m, correspondant à une incertitude relative de 37 ppm (part-perbillion) a été obtenue. Le résultat a été obtenu sur la base d'une méthode de traitement du signal de comptage de franges. La grande précision a été obtenue grâce au grand nombre de sous-mesures et à la stabilité des lignes de peigne régulièrement espacées. Nous avons constaté que la mesure de vibration de la cible peut également être effectuée en prenant avantage des lignes de peigne denses. Une sensibilité élevée, limitée à 1,7 nm efficace en bruit, de la mesure des vibrations a été atteinte. Ce résultat nous permet de surveiller la vibration de la cible, ce qui est un problème important de la technique FSI. / In this thesis, we implemented a high-precision absolute distance measurement (ADM) system using frequency sweeping interferometry (FSI). The FSI technique requires the frequency tuning range of the swept laser to be measured with high accuracy and precision, which is challenging due to the lack of an easy way to measure the high frequency of a laser in real time. In this thesis, a frequency comb has been used as the light frequency ruler for measuring the frequency tuning range of the sweeping laser. A frequency comb formed by a femtosecond laser consists millions of evenly spaced comb lines so that can be regarded as a light frequency ruler. The frequency calibration was realized by filtering the heterodyne signal between the sweeping laser and the comb lines using a narrow bandpass filter. This approach allows us to detect the calibration signal when the frequency of the sweeping laser is in the vicinity of a comb line. As the frequency interval between the comb lines space can be precisely measured or actively phase-locked against a stable radio-frequency (RF) oscillator, the tuning range of the sweeping laser could be measured with high accuracy. Especially, each two calibration peaks can be used in the calculation of distance, which we call sub-measurements in a single sweeping. Combined with the large number of the comb lines, averaging of the sub-measurements improves greatly the measurement precision without multiple sweeping. In the thesis, the condition of detecting and the characteristics of the heterodyne signal between the sweeping laser and the comb line are presented. A filter design for filtering the heterodyne signal is performed. A modeling work concerning the effect of the phase noise of lasers on the envelope distortion of the calibration peak has been presented. Experimental works based on the measurement concepts have been carried out. It shows that using the proposed measurement scheme can greatly improve the distance measurement precision. In one of the measurements, a precision of 30 nm for a distance around 0.8 m, corresponding to 37 ppb (part-per-billion) relative uncertainty has been achieved. The result was obtained based on a fringe counting signal processing method. The high precision was obtained thanks to the large number of sub-measurements and the stability of the evenly spaced comb lines. We have found that vibration measurement of the target can be also performed taking the advantage of the dense comb lines. A high sensitivity, limited by 1.7 nm noise RMS, of vibration measurement has been achieved. This result allows us to monitor the vibration of the target, which is an important issue of FSI technique. Mesure de distance absolue Peigne de fréquence Étalonnage de la fréquence Absolute distance measurement Frequency comb Frequency sweeping interferometry Frequency calibration 530.14 530.7 621.36
87	Toward an energy harvester for leadless pacemakers Deterre, Martin 09 July 2013 (has links) (PDF) 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. Cardiac implant Leadless pacemaker Energy harvesting Flexible packaging Electrodeposited bellows Electrostatic transducer Multi-layer comb structure Piezoelectric transducer Piezoelectric spiral
88	Multisensor Segmentation-based Noise Suppression for Intelligibility Improvement in MELP Coders Demiroglu, Cenk 18 January 2006 (has links) This thesis investigates the use of an auxiliary sensor, the GEMS device, for improving the quality of noisy speech and designing noise preprocessors to MELP speech coders. Use of auxiliary sensors for noise-robust ASR applications is also investigated to develop speech enhancement algorithms that use acoustic-phonetic properties of the speech signal. A Bayesian risk minimization framework is developed that can incorporate the acoustic-phonetic properties of speech sounds and knowledge of human auditory perception into the speech enhancement framework. Two noise suppression systems are presented using the ideas developed in the mathematical framework. In the first system, an aharmonic comb filter is proposed for voiced speech where low-energy frequencies are severely suppressed while high-energy frequencies are suppressed mildly. The proposed system outperformed an MMSE estimator in subjective listening tests and DRT intelligibility test for MELP-coded noisy speech. The effect of aharmonic comb filtering on the linear predictive coding (LPC) parameters is analyzed using a missing data approach. Suppressing the low-energy frequencies without any modification of the high-energy frequencies is shown to improve the LPC spectrum using the Itakura-Saito distance measure. The second system combines the aharmonic comb filter with the acoustic-phonetic properties of speech to improve the intelligibility of the MELP-coded noisy speech. Noisy speech signal is segmented into broad level sound classes using a multi-sensor automatic segmentation/classification tool, and each sound class is enhanced differently based on its acoustic-phonetic properties. The proposed system is shown to outperform both the MELPe noise preprocessor and the aharmonic comb filter in intelligibility tests when used in concatenation with the MELP coder. Since the second noise suppression system uses an automatic segmentation/classification algorithm, exploiting the GEMS signal in an automatic segmentation/classification task is also addressed using an ASR approach. Current ASR engines can segment and classify speech utterances in a single pass; however, they are sensitive to ambient noise. Features that are extracted from the GEMS signal can be fused with the noisy MFCC features to improve the noise-robustness of the ASR system. In the first phase, a voicing feature is extracted from the clean speech signal and fused with the MFCC features. The actual GEMS signal could not be used in this phase because of insufficient sensor data to train the ASR system. Tests are done using the Aurora2 noisy digits database. The speech-based voicing feature is found to be effective at around 10 dB but, below 10 dB, the effectiveness rapidly drops with decreasing SNR because of the severe distortions in the speech-based features at these SNRs. Hence, a novel system is proposed that treats the MFCC features in a speech frame as missing data if the global SNR is below 10 dB and the speech frame is unvoiced. If the global SNR is above 10 dB of the speech frame is voiced, both MFCC features and voicing feature are used. The proposed system is shown to outperform some of the popular noise-robust techniques at all SNRs. In the second phase, a new isolated monosyllable database is prepared that contains both speech and GEMS data. ASR experiments conducted for clean speech showed that the GEMS-based feature, when fused with the MFCC features, decreases the performance. The reason for this unexpected result is found to be partly related to some of the GEMS data that is severely noisy. The non-acoustic sensor noise exists in all GEMS data but the severe noise happens rarely. A missing data technique is proposed to alleviate the effects of severely noisy sensor data. The GEMS-based feature is treated as missing data when it is detected to be severely noisy. The combined features are shown to outperform the MFCC features for clean speech when the missing data technique is applied. Speech intelligibility Speech quality GEMS Multi-sensor Automatic speech recognition Speech enhancement Segmentation-based enhancement Noise-robust automatic segmentation Comb filter Data marginalization Data fusion Missing data
89	Cavity enhanced optical sensing / Kavitetsförstärkt optisk detektion Silander, Isak January 2015 (has links) An optical cavity comprises a set of mirrors between which light can be reflected a number of times. The selectivity and stability of optical cavities make them extremely useful as frequency references or discriminators. With light coupled into the cavity, a sample placed inside a cavity will experience a significantly increased interaction length. Hence, they can be used also as amplifiers for sensing purposes. In the field of laser spectroscopy, some of the most sensitive techniques are therefore built upon optical cavities. In this work optical cavities are used to measure properties of gas samples, i.e. absorption, dispersion, and refractivity, with unprecedented precision. The most sensitive detection technique of all, Doppler-broadened noise-immune cavity enhanced optical heterodyne molecular spectrometry (Db NICE-OHMS), has in this work been developed to an ultra-sensitive spectroscopic technique with unprecedented detection sensitivity. By identifying limiting factors, realizing new experimental setups, and determining optimal detection conditions, the sensitivity of the technique has been improved several orders of magnitude, from 8 × 10-11 to 9 × 10-14 cm-1. The pressure interval in which NICE-OHMS can be applied has been extended by derivation and verification of dispersions equations for so-called Dicke narrowing and speed dependent broadening effects. The theoretical description of NICE-OHMS has been expanded through the development of a formalism that can be applied to the situations when the cavity absorption cannot be considered to be small, which has expanded the dynamic range of the technique. In order to enable analysis of a large number of molecules at their most sensitive transitions (mainly their fundamental CH vibrational transitions) NICE-OHMS instrumentation has also been developed for measurements in the mid-infrared (MIR) region. While it has been difficult to realize this in the past due to a lack of optical modulators in the MIR range, the system has been based on an optical parametric oscillator, which can be modulated in the near-infrared (NIR) range. As the index of refraction can be related to density, it is possible to retrieve gas density from measurements of the index of refraction. Two such instrumentations have been realized. The first one is based on a laser locked to a measurement cavity whose frequency is measured by compassion with an optical frequency comb. The second one is based on two lasers locked to a dual-cavity (i.e. one reference and one measurement cavity). By these methods changes in gas density down to 1 × 10-9 kg/m3 can be detected. All instrumentations presented in this work have pushed forward the limits of what previously has been considered measurable. The knowledge acquired will be of great use for future ultrasensitive cavity-based detection methods. Optical resonators Fiber Laser Parametric oscillators Optical frequency comb Infrared Spectroscopy heterodyne Spectroscopy molecular Absorption Dispersion Lineshapes Optical standards and testing Refractivety measurements
90	Interação de um trem de pulsos ultracurtos com vapor de Rb: análise da linha D2 WONG, Alexis Carlos García 26 July 2016 (has links) Submitted by Irene Nascimento (irene.kessia@ufpe.br) on 2017-04-25T19:25:57Z No. of bitstreams: 2 license_rdf: 1232 bytes, checksum: 66e71c371cc565284e70f40736c94386 (MD5) ACGW_Dissertação.pdf: 2393143 bytes, checksum: 1dc4bede5ad081bffd11e546c86a753a (MD5) / Made available in DSpace on 2017-04-25T19:25:58Z (GMT). No. of bitstreams: 2 license_rdf: 1232 bytes, checksum: 66e71c371cc565284e70f40736c94386 (MD5) ACGW_Dissertação.pdf: 2393143 bytes, checksum: 1dc4bede5ad081bffd11e546c86a753a (MD5) Previous issue date: 2016-07-26 / CNPQ / Apresentamos um estudo da interação de um laser de femtosegundos de Ti:safira, com alta taxa de repetição, com vapor atômico de Rubídio. Trabalhamos no regime de acumulação coerente, em que o tempo de relaxação dos átomos do meio é maior que o tempo entre os pulsos. Para sondar a excitação produzida pelo laser pulsado sobre os vários grupos de velocidades atômicos usamos um laser contínuo de diodo. Estudamos a transmissão do laser de diodo em função de sua frequência, na presença e na ausência do laser pulsado, quando ambos os lasers estão sintonizados na transição 5S1=2 !5P3=2. Os resultados experimentais mostram que a transmissão do laser de diodo aumenta ou diminui dependendo do modo do pente de frequências que está interagindo com o grupo de átomos. Descrevemos os resultados experimentais trabalhando no domínio da frequência e modelando o meio atômico por um conjunto de dois sistemas de três níveis tipo L e um sistema de dois níveis, todos independentes entre si, interagindo com os modos do pente de frequência. Assim, a modelagem teórica considera os vários níveis hiperfinos e discrimina a interação com a transição cíclica do efeito de bombeio ótico, apresentado um resultado em concordância com os dados experimentais obtidos. O experimento foi realizado sem travar a taxa de repetição nem a frequência de off-set do laser de femtosegundos. / We present a study of the interaction of a high repetition rate femtosecond Ti:sapphire laser with a vapor atomic rubidium. We work on coherent accumulation regime, in which the atomic relaxation time is greater than the time interval between pulses. The action of the ultrashortpulsed laser over different atomic velocity groups is probed by a diode laser. We studied the transmission of the diode laser as a function of frequency, with and without the presence of the ultrashort-pulsed laser, when both lasers are tuned to 5S1=2!5P3=2 transition. The experimental results show that the diode laser transmission increases or decreases depending on the mode of the frequency comb that interacts with different velocity groups. The experimental results are described in the frequency domain and the atomic system is modeled by a set of two threelevel L systems and a system of two-level all independent and interacting with the frequency comb modes. The theoretical treatment considers the hyperfine transitions and distinguishes the interaction between the cyclic transitions from optical pumping effect, showing results in good agreement with the experimental data. The experiment is performed without lock repetition rate or the off-set frequency of the femtosecond Ti:sapphire laser.

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