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Laser studies of species involved in plasma etching processesBooth, J. P. January 1988 (has links)
No description available.
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Laser fluorescence studies of reactive and inelastic processes in molecular beamsFletcher, I. W. January 1984 (has links)
No description available.
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Passive Scalar Measurements In Actively Excited Free Shear FlowsMarques, Steven Joseph Jr. 17 August 1998 (has links)
The objectives of this study were to implement a system to measure mixing in nonreacting flows and to study the mass transfer characteristics of two actively excited turbulent jets. This thesis describes the acquisition and analysis of phase-locked concentration field data using planar Mie scattering from smoke particles and planar laser-induced fluorescence of acetone. Both techniques were shown to be effective in providing information for the actively excited nozzles. However, the laser-induced fluorescence technique was superior for revealing detail in the flowfield structure.
Spatial mode control techniques were applied to a triangular nozzle with vibrating actuators as the three sides and a swirl nozzle with pulsating tangential air jets. The effect of the different spatial modes on jet column development and the far fields of both nozzles is presented. Two- and three-dimensional iso-intensity contours, showing the relative intensity of light scattered by the nozzle fluid marker, were generated to show the flow structure. The areas inside the iso-intensity contours in the far field were also measured to determine relative effectiveness of nozzle fluid transport.
Large scale structures were visible in the three-dimensional iso-intensity contours from both nozzles. In addition, the transport of seeded nozzle fluid was enhanced by the spatial mode excitation for both nozzles. Spatial mode excitation was also able to affect the shape of the far field contour. In particular, the first counterrotating helical mode, m=±1, generated the greatest effect on nozzle fluid transport and the most pronounced elliptical contour shape in the far field. / Master of Science
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Laser Spectroscopy Sensors for Measurement of Trace Gaseous FormaldehydeBoddeti, Ravi K. 05 September 2008 (has links)
No description available.
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Three Dimensional Laser Diagnostics for Turbulent Flows and FlamesXu, Wenjiang 01 November 2017 (has links)
Due to their scientific significance and practical applications, turbulent flows and flames have been under extensive and intensive research for a long time. Turbulent flows and flames of interests to practice inherently have three-dimensional (3D) spatial structures, and therefore diagnostic techniques that can instantaneously resolve their 3D spatial features have long been desired and probably are needed to ultimately answer some of the open research questions. The goal of this dissertation thus is to investigate such diagnostics and demonstrate their capability and limitations in a range of turbulent flows/flames. To accomplish this goal, this dissertation developed and evaluated the following three diagnostic methods: tomographic chemiluminescence (TC), volumetric laser induced fluorescence (VLIF), and super-resolution planar laser induced fluorescence (SR-PLIF).
First, 3D flame topography of well-controlled laboratory flames was measured with TC method and validated by a simultaneous 2D Mie scattering measurement. The results showed that the flame topography obtained from TC and the Mie scattering agreed qualitatively, but quantitative difference on the order of millimeter was observed between these two methods. Such difference was caused by the limitations of the TC method. The first limitation involves TC's reliance on chemiluminescence of nascent radicals (mainly CH*) in reacting flows, causing ambiguity in the definition of flame front and limiting its applications to certain types of reactive flow only. The second limitation involves TC's inability to study an isolated region of interest because the chemiluminescence is emitted everywhere in the flame.
Based on the above understanding of the TC technique, the second part of this dissertation studied a VLIF method to overcome the above limitations of the TC technique. Compared with the TC technique, the VLIF method can be used in either reacting or non-reacting flow and on any particular region of interest. In the VLIF technique, the fluorescence signal was generated by exciting a target species with a laser slab of certain thickness. The signal was recorded by cameras from different perspectives, and then a VLIF tomographic algorithm was applied to resolve the spatial distribution of the concentration of the target species. An innovative 3D VLIF algorithm was proposed and validated by well-designed experiment. This model enables analysis of VLIF performance in terms of signal level, size of the field of view in 3D, and accuracy. However, due to the limited number of views and the tomographic reconstruction itself, the spatial resolution of VLIF methods is limited.
Hence, the third part of this dissertation investigated a SR-PLIF method to provide a strategy to improve the spatial resolution in two spatial directions, and also to extend the measurement range of scanning 3D imaging strategies. The SR-PLIF method used planar images captured simultaneously from two (or more) orientations to reconstruct a final image with resolution enhanced or blurring removed. Both the development of SR algorithm, and the experimental demonstration of the SR-PLIF method were reported. / Ph. D. / Optical diagnostics have become indispensable tools for the study of the turbulent flows and flames. Due to the inherently 3D structure of turbulent flows and flames, diagnostic techniques which can provide 3D measurements have been long desired. Therefore, this dissertation reports the development of three optics diagnostic methods that can provide such measurement capability, with a detailed discussion of their capabilities and limitations. The methods studied are tomographic chemiluminescence (TC), volumetric laser-induced fluorescence (VLIF), and super-resolution planar laser induced fluorescence (SR-PLIF). For the TC technique, the emission of light from combustion radicals (CH* and OH*) was recorded by multiple cameras placed at different orientations. A numerical algorithm was then applied to reconstruct the 3D flame structure. For the VLIF technique, a laser slab was used to excite a specific chemical species in the flame, which were captured from different perspectives to reconstruct the flow or flame structure in 3D. For the SR-PLIF technique, a series of planar images were recorded from multiple orientations to reconstruct a target image with higher resolution or to extend the measurement volume of scanning 3D diagnostics.
It is expected that the results obtained in this dissertation lay the groundwork for further development and expanded application of 3D diagnostics for the study of turbulent flows and combustion processes.
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4D combustion and flow diagnostics based on tomographic chemiluminescence (TC) and volumetric laser-induced fluorescence (VLIF)Wu, Yue 02 December 2016 (has links)
Optical diagnostics have become indispensable tools for the study of turbulent flows and flames. However, optical diagnostics developed in the past have been primarily limited to measurements at a point, along a line, or across a two-dimensional (2D) plane; while turbulent flows and flames are inherently four-dimensional (three-dimensional in space and transient in time). As a result, diagnostic techniques which can provide 4D measurement have been long desired. The purpose of this dissertation is to investigate two of such 4D diagnostics both for the fundamental study of turbulent flow and combustion processes and also for the applied research of practical devices. These two diagnostics are respectively code named tomographic chemiluminescence (TC) and volumetric laser induced fluorescence (VLIF). For the TC technique, the emission of light as the result of combustion (i.e. chemiluminescence) is firstly recorded by multiple cameras placed at different orientations. A numerical algorithm is then applied on the data recorded to reconstruct the 4D flame structure. For the VLIF technique, a laser is used to excite a specific species in the flow or flame. The excited species then de-excite to emit light at a wavelength longer than the laser wavelength. The emitted light is then captured by optical sensors and again, the numerical algorithm is applied to reconstruct the flow or flame structure. This dissertation describes the numerical and experimental validation of these two techniques, and explores their capabilities and limitations. It is expected that the results obtained in this dissertation lay the groundwork for further development and expanded application of 4D diagnostics for the study of turbulent flows and combustion processes. / Ph. D. / Optical diagnostics have become indispensable tools for the study of turbulent flows and flames. However, optical diagnostics developed in the past have been primarily limited to measurements at a point, along a line, or across a two-dimensional (2D) plane; while turbulent flows and flames are inherently four-dimensional (three-dimensional in space and transient in time). As a result, diagnostic techniques which can provide 4D measurement have been long desired. The purpose of this dissertation is to investigate two of such 4D diagnostics both for the fundamental study of turbulent flow and combustion processes and also for the applied research of practical devices. These two diagnostics are respectively code named tomographic chemiluminescence (TC) and volumetric laser induced fluorescence (VLIF). For the TC technique, the emission of light as the result of combustion (i.e. chemiluminescence) is firstly recorded by multiple cameras placed at different orientations. A numerical algorithm is then applied on the data recorded to reconstruct the 4D flame structure. For the VLIF technique, a laser is used to excite a specific species in the flow or flame. The excited species then de-excite to emit light at a wavelength longer than the laser wavelength. The emitted light is then captured by optical sensors and again, the numerical algorithm is applied to reconstruct the flow or flame structure. This dissertation describes the numerical and experimental validation of these two techniques, and explores their capabilities and limitations. It is expected that the results obtained in this dissertation lay the groundwork for further development and expanded application of 4D diagnostics for the study of turbulent flows and combustion processes.
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Technique for imaging ablation-products transported in high-speed boundary layers by using naphthalene planar laser-induced fluorescenceLochman, Bryan John 20 December 2010 (has links)
A new technique is developed that uses planar laser-induced fluorescence (PLIF) imaging of sublimated naphthalene to image the transport of ablation products in a hypersonic boundary layer. The primary motivation for this work is to understand scalar transport in hypersonic boundary layers and to develop a database for validation of computational models. The naphthalene is molded into a rectangular insert that is mounted flush with the floor of a Mach 5 wind tunnel. The distribution of naphthalene in the boundary layer is imaged by using PLIF, where the laser excitation is at 266 nm and the fluorescence is collected in the range of 320 to 380 nm. To investigate the use of naphthalene PLIF as a quantitative diagnostic technique, a series of experiments is conducted to determine the linearity of the fluorescence signal with laser fluence, as well as the temperature and pressure dependencies of the signal. The naphthalene fluorescence at 297 K is determined to be linear for laser fluence that is less than about 200 J/m². The temperature dependence of the naphthalene fluorescence signal is found at atmospheric pressure over the temperature range of 297K to 525K. A monotonic increase in the fluorescence is observed with increasing temperature. Naphthalene fluorescence lifetime measurements were also made in pure-air and nitrogen environments at 300 K over the range 1 kPa to 40 kPa. The results in air show the expected Stern-Volmer behavior with decreasing lifetimes at increasing pressure, whereas nitrogen exhibits the opposite trend. Preliminary PLIF images of the sublimated naphthalene are acquired in a Mach 5 turbulent boundary layer. Relatively low signal-to-noise-ratio images were obtained at a stagnation temperature of 345 K, but much higher quality images were obtained at a stagnation temperature of 380 K. The initial results indicate that PLIF of sublimating naphthalene may be an effective tool for studying scalar transport in hypersonic flows. / text
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Development and application of optical diagnostic techniques for assessing the effects of preferential evaporation of multi-component fuels under engine-relevant conditions / Développement et exploitation de techniques de diagnostics optiques pour la compréhension de l'évaporation de carburants mufti-composants dans les moteurs essenceItani, Lama 14 December 2015 (has links)
Dans le cadre de cette thèse, une technique de diagnostic optique a été développée pour mesurer simultanément l’évaporation différentielle, la distribution de température, et la concentration massique de fuel dans un jet multi-composant. Cette technique a été examinée dans les conditions d’un moteurs essence. La technique de mesure est basée sur l’utilisation des deux traceurs excités par une seule longueur d’onde.Pour pouvoir examiner l’évaporation différentielle d’un carburant multi-composant, deux traceurs ont été sélectionnés : le p-difluorobenzène et le 1-methylnaphtalène. Ces traceurs reproduisent deux types de volatilité : faible et moyenne à élevée. Les traceurs choisis fluorescent dans deux régions spectrales distinctes ce qui rend l’application de cette technique possible. Une étude photophysique a été menée pour caractériser les deux traceurs, indépendamment puis en mélange, pour différentes conditions de pression, température, et composition du bain gazeux. L’étude photophysique est essentielle pour pouvoir mesurer quantitativement l’évaporation différentielle. Les résultats photophysiques montrent que le spectre du 1-methylnaphthalène est sensible à la température. Cette caractéristique permet de mesurer la distribution en température dans le jet.Les essais ont été réalisés dans une cellule haute pression / haute température, ca-pable de simuler les conditions d’un moteur thermique. Des sprays générés par un injecteur ECN Spray G et un piézo-électrique d’une ouverture annulaire ont été étudiés. Des mesures initiales ont été menées avec chaque traceur pour pouvoir fixer la proportion de mélange des traceurs. La précision de la méthode de mesure a été calculée suivant une configuration de filtres identiques. Ensuite, les champs de tempé-rature calculés par la LIF et ceux déterminés depuis les champs de concentration massique, ont été comparés. Les résultats démontrent que la température est homo-gène ce qui signifie que les mesures d’évaporation différentielle n’ont pas influencé par la distribution de température dans le jet.Les images obtenues en détectant les signaux depuis le mélange de traceurs ont permis de localiser l’évaporation différentielle. Une variation en distribution spatiale des composants est observée 550–600 K. Cet effet disparaît en augmentant la température, ce qui explique que l’évaporation est plus rapide à haute température. La localisation de l’évaporation différentielle varie avec le type d’injecteur. La géométrie du nez ainsi que la structure du jet a donc un impact sur la formation du mélange. / A non-intrusive quantitative laser-induced fluorescence (LIF) technique capable of simultaneously measuring preferential evaporation, temperature distribution, and fuel-mass concentration across a multi-component vaporized spray has been developed and investigated under engine-relevant conditions. The measurement technique is based on two-tracer LIF with single wavelength excitation.To assess preferential evaporation, a tracer pair with suitable co-evaporation and spectral properties was selected based on vapor-liquid equilibrium calculations repre-sentative for gasoline fuels. Evaporation studies have shown that one tracer (p-difluoro-benzene) co-evaporates with the high-to-medium-volatility end of the multi-component fuel while the other (1-methylnaphthalene) co-evaporates with the low-volatility end. For quantitative measurements the photophysical properties of both tracers (each tracer separately and the combined tracers) were determined under a wide range of pressure, temperature, and bath-gas composition conditions. 1-methylnaphthalene LIF shows a strong red-shift with temperature which enables measurements of the temperature distribution across the spray.Spray evaporation and vapor mixing experiments were performed in a high-pressure high-temperature vessel capable of simulating in-cylinder conditions. An ECN Spray-G and a piezo-electric outward opening injector were used in this study. Initial measure-ments were carried out with each tracer added separately to the fuel to assess signal cross-talk and to determine the best tracer concentrations. Once the proportions were determined, accuracy and precision of the method were determined from the LIF-signal ratio of spray images within identical spectral bands. Temperature fields, obtained by two-color 1-methylnaphthalene LIF and derived from fuel concentration maps based on the assumption of adiabatic evaporation, were examined for inhomogeneities in the area of interest since fluctuations potentially influence the two-color method. It was shown that the temperature is homogeneous in the measurement volume.To localize preferential evaporation, two-color two-tracer LIF images were evaluated. Taking into account the measurement accuracy and precision, variations in the spatial distribution of the fuel volatility classes were observed for 550–600 K. At higher tem-peratures, the effect is less pronounced, which is consistent with the fact that evapora-tion is faster. The localization of preferential evaporation varied with each injector used indicating the impact of injector nozzle geometry and jet structure on mixture formation. / Eine berührungsfreies quantitatives Verfahren auf Basis von laserinduzierter Fluoreszenz (LIF) wurde entwickelt, um simultan präferenzielle Verdampfung, Temperaturverteilung und Kraftstoffkonzentration im verdampften Bereich eines Mehrkomponenten-Kraftstoffsprays unter motorrelevanten Bedingungen zu messen. Verfahren beruht auf Zwei-tracer-LIF mit Anregungmit einem Laser.Es wurde ein Tracer-Paar mit geeigneten Verdampfungs- und spektralen Eigenschaften auf Basis von Dampf-Flüssigkeits-Gleichgewichtsrechnungen für Otto-Kraftstoffe ausgewählt. Verdampfungsmessungen haben gezeigt, dass ein Tracer (p-Difluorbenzol) gleichzeitig mit dem mittel- und höherflüchtigen Siedeklassen verdampft, während der andere (1-Methylnaphthalin) den schwerflüchtigen Komponentenfolgt. Für quantitative Messungen wurden die photophysikalischen Eigenschaften beider Tracer (einzeln und als Kombination) in einem weiten Bereich von Druck, Temperatur und Gaszusammensetzung bestimmt. 1-Methylnaphthalin-LIF zeigt eine starke Rotverschiebung mit der Temperatur, die Messungen der Temperaturverteilung ermöglicht. Es wurde ein Tracer-Paar mit geeigneten Verdampfungs- und spektralen Eigenschaften auf Basis von Dampf-Flüssigkeits-Gleichgewichtsrechnungen für Otto-Kraftstoffe ausgewählt. Verdampfungsmessungen haben gezeigt, dass ein Tracer (p-Difluorbenzol) gleichzeitig mit dem mittel- und höherflüchtigen Siedeklassen verdampft, während der andere (1-Methylnaphthalin) den schwerflüchtigen Komponentenfolgt. Für quantitative Messungen wurden die photophysikalischen Eigenschaften beider Tracer (einzeln und als Kombination) in einem weiten Bereich von Druck, Temperatur und Gaszusammensetzung bestimmt. 1-Methylnaphthalin-LIF zeigt eine starke Rotverschiebungmit der Temperatur, die Messungen der Temperaturverteilung ermöglicht.
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Low temperature laser-induced fluorescence studies of chromophores in soft solids and biological matterLin, Chen January 1900 (has links)
Doctor of Philosophy / Department of Chemistry / Ryszard J. Jankowiak / Low-temperature laser-induced fluorescence spectroscopy has various applications in analytical, physical, and biophysical chemistry. This technique provides information on the fluorescence origin band, zero-phonon lines and phonon-sidebands, inhomogeneous broadening, electron-phonon coupling strength, and ground- and excited-state vibrational frequencies of studied molecules. Examples discussed in this work include studies of DNA/metabolites and monoclonal antibody (mAb)/antigen interactions. The structural basis for the increased reactivity of BPDE towards guanines at 5-methylcytosine ([superscript]M[superscripte]eC):G sites in DNA was investigated by low temperature laser-based spectroscopy, studying the nature of physical complexes of benzo[a]pyrene tetraol in a series of 5-methylcytosine structural DNA analogs. We found that the presence of a C-5 substituent on cytosine and related structural modifications influences the conformation of BPT in DNA analogs, and could explain the increase in guanine reactivity at [superscript]M[superscript]eC:G sites of the p53 tumor suppressor gene that contains endogenenous 5-([superscript]M[superscript]eC. It has been demonstrated that various mAbs can bind a particular cross-reactant by adopting two distinct "red" and "blue" conformations of its binding sites. We showed that the blue conformation of pyrene in several mAbs (including 4D5 mAb) is consistent with [pi]-cation interactions, underscoring the importance of [pi]-cation interaction in ligand binding. We propose that considerable narrowing of the fluorescence origin band of the ligand in the protein environment could be regarded as a simple indicator of [pi]-cation interactions. It is also shown that time-resolved delta fluorescence line-narrowing ([delta]FLN) spectroscopy, using excitation within the (0,0)-transition band, provides more reliable information of the frequency dependence of the electron-phonon coupling (Huang-Rhys factor, (S < 1). Finally, analytical formulas were developed to describe FLN spectra with excitation energy transfer present. Our calculated FLN spectra are compared with spectra obtained by a simple convolution method (SC) and a more rigorous treatment using Redfield theory. We demonstrate that, under the condition of weak coupling between pigments (i.e., the coupling constant is smaller than the reorganization energy) and weak electron-phonon coupling strength (S < 1), our analytical formulas provide an excellent approximation of the SC and Redfield methodologies. We argued that our approach could also model FLN spectra obtained for very complex biological systems.
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Ion Transport in a Commercial ICP-MSLarsen, Jessica Joline 01 July 2017 (has links)
The performance of an inductively coupled plasma mass spectrometer, ICP-MS, depends on the instrument's ability to transport sample ions through the vacuum interface and focus the ions into a well-defined beam that will eventually reach the mass analyzer. In this study two main experiments were performed on the Perkin Elmer NexION 300S, a commercial ICP-MS. First, planar laser-induced fluorescence images were taken of the ion beam in a working instrument downstream from a unique quadrupole ion deflector. The images showed the ability of the instrument design to focus the ions in the ion beam. Second, laser-induced fluorescence was used to characterize ion flow through the vacuum interface. The interface is unique to the NexION ICP-MS in that there are three extraction cones. The effect of a three-cone interface on ideal skimming is discussed.
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