Global ETD Search

81	The measurement of the directional frequency response of microphones in ordinary rooms using fast Fourier transform analysis / Perron, Serge. January 1984 (has links) No description available. Spectrum analysis. Microphone -- Calibration. Microphone. Fourier transform spectroscopy.
82	Fourier transform infrared spectrometric detection of chromatographic effluents: instrumental and methodological improvements using a flow cell interface Johnson, Charles Clifford January 1985 (has links) The Fourier Transform Infrared spectrometer (FTIR) has been used increasingly as a detector for various forms of chromatography. Clearly the most established marriage has been that of the Gas Chromatograph (GC) with the FTIR. GC-FTIR has been developed well beyond other forms. The main objective of this thesis, however, is to extend the FTIR as a detector to previously untested forms of chromatography using a flow cell interface. These forms of chromatography include High Performance Liquid Chromatography (HPLC), both normal-phase and reversed-phase, and packed-column Supercritical Fluid Chromatography (SFC). Normal phase HPLC-FTIR was demonstrated on not only analytical scale columns, but semi-preparative and microbore scales as well. Significant advantages, particularly with respect to the low solvent consumption, were found in the microbore HPLC-FTIR experiment. This led to the development of a chromatographically improved flow cell, the Zero Dead Volume (ZDV) HPLC-FTIR interface. The ZDV cell shows superior chromatographic characteristics and has unique spectrometric characteristics because of its unusual cross-section. Detection limits as low as 40 ng were observed. Extension to reversed-phase HPLC-FTIR required incorporation of the Flow Injection Analysis (FIA) technique of low-dispersion flowing extraction. The compounds separated by HPLC are extracted into an infrared-transparent solvent, and the extracted compounds are detected by similar means to normal-phase HPLC-FTIR. Investigation of SFC-FTIR incorporated a high-pressure, gold-lined lightpipe flow cell to detect the components separated by the supercritical C0₂/packed-column chromatograph. Several unusual spectrometric characteristics were noted. Detection limits as low as 50 ng were observed with SFC-FTIR. / Ph. D. LD5655.V856 1985.J632 Infrared spectroscopy -- Experiments Liquid chromatography -- Experiments
83	Construction and Analysis of a Microwave-induced Plasma Lamp for Precision Spectroscopy Boesch, Andreas 16 March 2016 (has links) No description available. 530 Physik (PPN621336750) wavelength calibration astronomical instrumentation Fourier transform spectroscopy high-precision radial velocities microwave-induced plasma molecular emission spectra
84	Small Angle Light Scattering Analysis of Tissue Dahlgren, Eric D 11 January 2002 (has links) Tissue, in particular its mechanical properties, is of interest from a material science point of view. The collagen fiber framework found in nearly all tissue forms the basis for the tissue's behavior. Connective tissue provides more interesting behavior, designed to bear significant load in one direction, while retaining the ability to stretch in other directions. Contributing factors to such behavior are fiber diameter and orientation. Small angle scattering analysis has been developed over the past century. Particular attention has been paid to x-ray and neutron scattering, both of which characterize features on a nanometer scale. Small angle light scattering (SALS) has the ability to characterize features on a micron scale, and is thus suitable for the analysis of collage fibers. Scattering data from several tendons were analyzed using the Generalized Indirect Fourier Transform (GIFT) program developed by Dr. Otto Glatter. The data is fit using cubic B-splines, and transformed into a probability density distribution function (abbreviated PDDF or p(r)). The PDDF can then be interpreted to give an average fiber diameter, as well as other structural information. Since this type of analysis has never been performed on collagen fibers, emphasis was placed on validating small angle light scattering as an appropriate technique to characterize collagen fiber diameter. This was accomplished by comparing the results with optical microscopy. Results from SALS analysis agree with features observed by optical microscopy. Small angle light scattering analysis is able to provide an analysis of structures superior to that of optical microscopy. Small angle scatter theory provides a three dimensional analysis of the structure. On the other hand, optical microscopy provides only a two dimensional view of the sample. The structure of collagen fibers in tissue is certainly three dimensional, making small angle light scattering a more suitable technique for characterization. cartilage tendon light scattering Tissues Mechanical properties Collagen Fourier transform spectroscopy Light scattering Small angle light scattering
85	Analysis and pre-processing of signals observed in optical feedback self-mixing interferometry Zhang, Xiaojun. January 2008 (has links) Thesis (M.E.-Res.)--University of Wollongong, 2008. / Typescript. Includes bibliographical references: p. 164-179.
86	Fourier transform and Vernier spectroscopy using optical frequency combs / Fouriertransform- och Vernierspektroskopi med optiska frekvenskammar Khodabakhsh, Amir January 2017 (has links) Optical frequency comb spectroscopy (OFCS) combines two previously exclusive features, i.e., wide optical bandwidth and high spectral resolution, enabling precise measurements of entire molecular bands and simultaneous monitoring of multiple gas species in a short measurement time. Moreover, the equidistant mode structure of frequency combs enables efficient coupling of the comb power to enhancement resonant cavities, yielding high detection sensitivities. Different broadband detection methods have been developed to exploit the full potential of frequency combs in spectroscopy, based either on Fourier transform spectroscopy or on dispersive elements.There have been two main aims of the research presented in this thesis. The first has been to improve the performance of mechanical Fourier transform spectrometers (FTS) based on frequency combs in terms of sensitivity, resolution and spectral coverage. In pursuit of this aim, we have developed a new spectroscopic technique, so-called noise-immune cavity-enhanced optical frequency comb spectroscopy (NICE-OFCS), and achieved a shot-noise-limited sensitivity and low ppb (parts-per-billion, 10−9) CO2 concentration detection limit in the near-infrared range using commercially available components. We have also realized a novel method for acquisition and analysis of comb-based FTS spectra, a so-called sub-nominal resolution method, which provides ultra-high spectral resolution and frequency accuracy (both in kHz range, limited only by the stability of the comb) over the broadband spectral range of the frequency comb. Finally, we have developed an optical parametric oscillator generating a frequency comb in the mid-infrared range, where the strongest ro-vibrational molecular absorption lines reside. Using this mid-infrared comb and an FTS, we have demonstrated, for the first time, comb spectroscopy above 5 μm, measured broadband spectra of several species and reached low ppb detection limits for CH4, NO and CO in 1 s.The second aim has been more application-oriented, focused on frequency comb spectroscopy in combustion environments and under atmospheric conditions for fast and sensitive multispecies detection. We have demonstrated, for the first time, cavity-enhanced optical frequency comb spectroscopy in a flame, detected broadband high temperature H2O and OH spectra using the FTS in the near-infrared range and showed the potential of the technique for flame thermometry. For applications demanding a short measurement time and high sensitivity under atmospheric pressure conditions, we have implemented continuous-filtering Vernier spectroscopy, a dispersion-based spectroscopic technique, for the first time in the mid-infrared range. The spectrometer was sensitive, fast, robust, and capable of multispecies detection with 2 ppb detection limit for CH4 in 25 ms. / Optisk frekvenskamspektroskopi (OFCS) kombinerar två tidigare icke förenliga egenskaper, dvs. ett brett optiskt frekvensområde med en hög spektral upplösning, vilket möjliggör noggranna mätningar av hela molekylära absorptionsband och detektion av flera gaser samtidigt med en kort mättid. Eftersom frekvenskammar har en regelbunden struktur med jämnt separerade laser moder kan man effektivt koppla kammen till en optisk kavitet och därmed möjliggöra frekvenskamsdetektion med hög känslighet. Olika metoder har utvecklats för att utnyttja frekvenskammarnas fulla potential för spektroskopi, baserad på antingen Fouriertransform-spektroskopi eller dispersiva element.Forskningen som presenteras i denna avhandling har haft två huvudmål. Det första har varit att förbättra prestandan hos mekaniska Fourier-transformspektrometrar (FTS) baserat på frekvenskammar med avseende på känslighet, upplösning och spektral täckning. I strävan efter detta har vi utvecklat en ny spektroskopisk teknik, benämnd brusimmun kavitetsförstärkt optisk frekvenskamspektroskopi (NICE-OFCS), och uppnått en hagelbrusbegränsad känslighet och detektionsgränser ner till låga ppb koncentrationer (miljarddelar, 10−9) för CO2 i det när-infraröda frekvensområdet enbart med användning av kommersiellt tillgängliga komponenter. Vi har också utvecklat en ny metod för insamling och analys av kambaserade FTS-spektra, som betecknas ha sub-nominell upplösning. Metoden gör det möjligt att uppnå ultrahög spektral upplösning och hög frekvensnoggrannhet (båda i kHz-området, endast begränsad av kammens stabilitet) över kammens hela frekvensområde. Slutligen har vi utvecklat en optisk parametrisk oscillator som genererar en frekvenskam i det mid-infraröda frekvensområdet, där de starkaste rotations-vibrationsmolekylära absorptionslinjerna finns. Med hjälp av denna kam och en FTS har vi för första gången demonstrerat frekvenskamspektroskopi över 5 μm. Vi har detekterat bredbandsspektra av flera molekylära gaser och har, för mättider på 1 s, uppnått detektionsgränser ner till låga ppb halter för CH4, NO och CO.Det andra syftet har varit mer applikationsorienterat: att använda frekvenskamspektroskopi i förbränningsmiljö och under atmosfäriska förhållanden för snabb och känslig multiämnesdetektion. Vi har för första gången demonstrerat kavitetsförstärkt optisk frekvenskamspektroskopi i en flamma, där vi har detekterat högtemperaturspektra av H2O och OH i det när-infraröda området med användning av FTS och visat teknikens potential för termometrisk karakterisering av flammor. För applikationer som kräver en kort mättid och hög känslighet under atmosfäriska förhållanden har vi utvecklat ett detektionssystem baserat på Vernier-spektroskopi med kontinuerlig filtrering, vilket är en dispersionsbaserad teknik, för första gången i det mid-infraröda frekvensområdet. Det befanns att spektrometern var känslig, snabb, robust och kapabel till multiämnesdetektion med en detektionsgräns på 2 ppb för CH4 för korta mättider (25 ms). optical frequency comb spectroscopy molecular absorption resonant cavity Fourier transform spectroscopy Vernier spectroscopy Atom and Molecular Physics and Optics Atom- och molekylfysik och optik
87	Coherent Response of Two Dimensional Electron Gas probed by Two Dimensional Fourier Transform Spectroscopy Paul, Jagannath 06 April 2017 (has links) Advent of ultrashort lasers made it possible to probe various scattering phenomena in materials that occur in a time scale on the order of few femtoseconds to several tens of picoseconds. Nonlinear optical spectroscopy techniques, such as pump-probe, transient four wave mixing (TFWM), etc., are very common to study the carrier dynamics in various material systems. In time domain, the transient FWM uses several ultrashort pulses separated by time delays to obtain the information of dephasing and population relaxation times, which are very important parameters that govern the carrier dynamics of materials. A recently developed multidimensional nonlinear optical spectroscopy is an enhanced version of TFWM which keeps track of two time delays simultaneously and correlate them in the frequency domain with the aid of Fourier transform in a two dimensional map. Using this technique, the nonlinear complex signal field is characterized both in amplitude and phase. Furthermore, this technique allows us to identify the coupling between resonances which are rather difficult to interpret from time domain measurements. This work focuses on the study of the coherent response of a two dimensional electron gas formed in a modulation doped GaAs/AlGaAs quantum well both at zero and at high magnetic fields. In modulation doped quantum wells, the excitons are formed as a result of the inter- actions of the charged holes with the electrons at the Fermi edge in the conduction band, leading to the formation of Mahan excitons, which is also referred to as Fermi edge singularity (FES). Polarization and temperature dependent rephasing 2DFT spectra in combination with TI-FWM measurements, provides insight into the dephasing mechanism of the heavy hole (HH) Mahan exciton. In addition to that strong quantum coherence between the HH and LH Mahan excitons is observed, which is rather surprising at this high doping concentration. The binding energy of Mahan excitons is expected to be greatly reduced and any quantum coherence be destroyed as a result of the screening and electron-electron interactions. Such correlations are revealed by the dominating cross-diagonal peaks in both one-quantum and two-quantum 2DFT spectra. Theoretical simulations based on the optical Bloch Equations (OBE) where many-body effects are included phenomenologically, corroborate the experimental results. Time-dependent density functional theory (TD-DFT) calculations provide insight into the underlying physics and attribute the observed strong quantum coherence to a significantly reduced screening length and collective excitations of the many-electron system. Furthermore, in semiconductors under the application of magnetic field, the energy states in conduction and valence bands become quantized and Landau levels are formed. We observe optical excitation originating from different Landau levels in the absorption spectra in an undoped and a modulation doped quantum wells. 2DFT measurements in magnetic field up to 25 Tesla have been performed and the spectra reveal distinct difference in the line shapes in the two samples. In addition, strong coherent coupling between landau levels is observed in the undoped sample. In order to gain deeper understanding of the observations, the experimental results are further supported with TD-DFT calculation. Mahan Exciton Modulation Doped Quantum Well 2D Electron Gas Quantum Coherence Magnetoexcitons Optics Physics
88	Exciton Dynamics and Many Body Interactions in Layered Semiconducting Materials Revealed with Non-linear Coherent Spectroscopy Dey, Prasenjit 17 March 2016 (has links) Atomically thin, semiconducting transition metal dichalogenides (TMDs), a special class of layered semiconductors, that can be shaped as a perfect two dimensional material, have garnered a lot of attention owing to their fascinating electronic properties which are achievable at the extreme nanoscale. In contrast to graphene, the most celebrated two-dimensional (2D) material thus far; TMDs exhibit a direct band gap in the monolayer regime. The presence of a non-zero bandgap along with the broken inversion symmetry in the monolayer limit brands semiconducting TMDs as the perfect candidate for future optoelectronic and valleytronics-based device application. These remarkable discoveries demand exploration of different materials that possess similar properties alike TMDs. Recently, III-VI layered semiconducting materials (example: InSe, GaSe etc.) have also emerged as potential materials for optical device based applications as, similar to TMDs, they can be shaped into a perfect two-dimensional form as well as possess a sizable band gap in their nano-regime. The perfect 2D character in layered materials cause enhancement of strong Coulomb interaction. As a result, excitons, a coulomb bound quasiparticle made of electron-hole pair, dominate the optical properties near the bandgap. The basis of development for future optoelectronic-based devices requires accurate characterization of the essential properties of excitons. Two fundamental parameters that characterize the quantum dynamics of excitons are: a) the dephasing rate, 𝛾, which represents the coherence loss due to the interaction of the excitons with their environment (for example- phonons, impurities, other excitons, etc.) and b) excited state population decay rate arising from radiative and non-radiative relaxation processes. The dephasing rate is representative of the time scale over which excitons can be coherently manipulated, therefore accurately probing the source of exciton decoherence is crucial for understanding the basic unexplored science as well as creating technological developments. The dephasing dynamics in semiconductors typically occur in the picosecond to femtosecond timescale, thus the use of ultrafast laser spectroscopy is a potential route to probe such excitonic responses. The focus of this dissertation is two-fold: firstly, to develop the necessary instrumentation to accurately probe the aforementioned parameters and secondly, to explore the quantum dynamics and the underlying many-body interactions in different layered semiconducting materials. A custom-built multidimensional optical non-linear spectrometer was developed in order to perform two-dimensional spectroscopic (2DFT) measurements. The advantages of this technique are multifaceted compared to regular one-dimensional and non-linear incoherent techniques. 2DFT technique is based on an enhanced version of Four wave mixing experiments. This powerful tool is capable of identifying the resonant coupling, probing the coherent pathways, unambiguously extracting the homogeneous linewidth in the presence of inhomogeneity and decomposing a complex spectra into real and imaginary parts. It is not possible to uncover such crucial features by employing one dimensional non-linear technique. Monolayers as well as bulk TMDs and group III-VI bulk layered materials are explored in this dissertation. The exciton quantum dynamics is explored with three pulse four-wave mixing whereas the phase sensitive measurements are obtained by employing two-dimensional Fourier transform spectroscopy. Temperature and excitation density dependent 2DFT experiments unfold the information associated with the many-body interactions in the layered semiconducting samples. Layered semiconductors dephasing exciton-phonon interaction homogeneous linewidth Condensed Matter Physics Physics
89	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
90	Astronomical submillimetre Fourier transform spectroscopy from the Herschel Space Observatory and the JCMT Jones, Scott Curtis, University of Lethbridge. Faculty of Arts and Science January 2010 (has links) Fourier transform spectroscopy (FTS) is one of the premier ways to collect source information through emitted radiation. It is so named because the principal measurement technique involves the analysis of spectra determined from the Fourier transform of a time-domain interference pattern. Given options in the field, many space- and ground-based instruments have selected Fourier transform spectrometers for their measurements. The Herschel Space Observatory, launched on May 14, 2009, has three on-board instruments. One, SPIRE, comprises a FTS paired with bolometer detector arrays. SCUBA-2 (Submillimetre Common User Bolometer Array) and FTS-2 have recently been commissioned and will be mounted within the collecting dish of the James Clerk Maxwell Telescope by Fall, 2010. The use of FTS in these two observatories will be examined. While work towards each project is independently useful, the thesis is bound by the commonality between the two, as each seeks similar answers from vastly different viewpoints. / xvii, 123 leaves : ill. (some col.) ; 29 cm Fourier transform spectroscopy Herschel Space Observatory (Spacecraft) James Clerk Maxwell Telescope Submillimeter astronomy Dissertations, Academic

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