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511	STRUCTURAL CHARACTERIZATION OF NATURAL GAS HYDRATES IN CORE SAMPLES FROM OFFSHORE INDIA Kumar, Pushpendra, Das, H.C., Anbazhagen, K., Lu, Hailong, Ripmeester, John A. 07 1900 (has links) The dedicated gas hydrate coring/drilling program was carried out under National Gas Hydrate Program (NGHP) in four Indian offshore areas (Kerala-Konkan, Krishna- Godavari, Mahanadi and Andman) during 28th April to 19th August, 2006. During NGHP Expedition 01, 2006, total of 39 holes were drilled/cored at 21 sites in these areas. The gas hydrates have been found to be present in large quantities in Indian offshore areas particularly in KG basin. More than 130 confirmed solid gas hydrate samples were recovered during this hydrate coring/drilling program. The laboratory analysis was carried out on the 34 natural gas hydrate samples recovered from offshore India. The gas hydrate characterization was carried out using the microscopic techniques such as Raman, 13C NMR and XRD for its structure, cavity occupancy and hydration number. The gas hydrates occur in grayish green fine sediments, gray medium sands and white volcanic ash as pore-filling hydrate and massive hydrates in fractured shale/clay. The visible massive gas hydrates developed especially at Site NGHP 1-10B, 10C, 10D and 21A in K G area. The structures of the gas hydrates in the studied samples are all sI, with methane as the dominant guest molecule. The occupancy of methane in large cage is almost complete, while it is variable in the small cage (0.75 to 0.99). The hydration number is 6.10 ± 0.15 for most of the hydrates in the samples studied. This paper presents the results of the laboratory analysis on the structural characterization of natural gas hydrates in core samples from offshore India. methane hydrate gas hydrate structure cavity occupancy hydration number ICGH 2008
512	Frequency-shifted Interferometry for Fiber-optic Sensing Ye, Fei 14 January 2014 (has links) This thesis studies frequency-shifted interferometry (FSI), a useful and versatile technique for fiber-optic sensing. I first present FSI theory by describing practical FSI configurations and discussing the parameters that affect system performance. Then, I demonstrate the capabilities of FSI in fiber-optic sensor multiplexing and high sensitivity chemical analysis. We implemented a cryogenic liquid level sensing system in which an array of 3 fiber Bragg grating (FBG) based sensors was interrogated by FSI. Despite sensors' spectral overlap, FSI is able to separate sensor signals according to their spatial locations and to measure their spectra, from which whether a sensor is in liquid or air can be unambiguously determined. I showed that a broadband source paired with a fast tunable filter can be used in FSI systems as the light source. An array of 9 spectrally overlapping FBGs was successfully measured by such a system, indicating the potential of system cost reduction as well as measurement speed improvement. I invented the the FSI-CRD technique, a highly sensitive FSI-based fiber cavity ring-down (CRD) method capable of deducing minuscule loss change in a fiber cavity from the intensity decay rate of continuous-wave light circulating in the cavity. As a proof-of-principle experiment, I successfully measured the fiber bend loss introduced in the fiber cavity with FSI-CRD, which was found to be 0.172 dB/m at a bend radius of 12.5 mm. We then applied FSI-CRD to evanescent-field sensing. We incorporated fiber tapers as the sensor head in the system and measured the concentration of 1-octyne solutions. A minimum detectable 1-octyne concentration of 0.29% was achieved with measurement sensitivity of 0.0094 dB/% 1-octyne. The same system also accurately detected the concentration change of sodium chloride (NaCl) and glucose solutions. Refractive index sensitivity of 1 dB/RIU with a measurement error of 1*10^-4 dB was attined for NaCl solutions. Finally, I proposed a theoretical model to study the polarization effects in FSI systems. Preliminary results show that the model can already explain the experimental observations. It not only provides insight into how to improve system performance but also suggests potential new applications of the technique. fiber-optics fiber-optic sensing cavity ring-down sensor multiplexing 0544 0752
513	Integrated dual frequency permittivity analyzer using cavity perturbation concept Meda, Venkatesh. January 2002 (has links) Optimal utilization of microwave energy requires more basic knowledge of the dielectric properties of the material under investigation. The dielectric properties of materials subjected to microwaves are known to depend on moisture content, temperature and density of the material as well as the frequency of the applied microwave field. This thesis is focussed on the development and evaluation of the new Permittivity Analyser to measure the dielectric properties of agri-food materials at 915 and 2450 MHz using cavity perturbation concept. / In this study, the dielectric properties measuring system was designed and developed using cavity perturbation concept to measure the essential and fundamental parameters of microwave-material interaction; dielectric constant and dielectric loss factor of selected agri-food substances and organic solvents. The TM010 mode of electromagnetic energy was selected and configured to operate at the peakresonant condition for both ISM (Industrial, Scientific and Medical) approved frequencies of .915 and 2450 MHz frequencies. The resonant perturbation cavities were designed, fabricated and tested using the network analyser and the permittivity analyser. High Q (ratio of energy supplied to absorbed) values were reported for both frequencies. Basic calibration of the measurement system was performed using standard media such as air, water and alcohol. Necessary mathematical steps and algorithms were written and integrated into a user-friendly software program (Visual basic 6.0) to carry out the entire measurement. / The dielectric properties (epsilon' & epsilon ″) of materials such as; edible oils---canola, soya and sunflower oils, neem oil/pulp, homogenized milk (1, 2 and 3.25% fat), organic solvents such as ethanol, hexane and their mixtures were determined at various temperatures and frequency (915, 2450 MHz) combinations, using cavity perturbation technique. Linear relationships between the dielectric properties and temperature found in the literature were confirmed to be valid for certain ranges in case of edible oils, organic solvents and milk samples tested with the cavity perturbation method. Repeatibility and variability aspects of the permittivity analyzer at both the frequencies are presented. Food industry and trade. Dielectric measurements. Cavity resonators.
514	RF compression of electron bunches applied to ultrafast electron diffraction Chatelain, Robert P., 1982- January 2008 (has links) The dynamics of atomic scale structures during structural change can be studied by Ultrafast Electron Diffraction (UED). The time resolution needed to reveal the fastest dynamics is 100 fs. Sub-angstrom structural resolution becomes possible with 1-1000 pC of charge necessary for diffraction pattern analysis during subtle structural changes. This combination of requirements cannot currently be realized due to the space-charge temporal broadening inherent to bunches of electrons of high fluence and short temporal duration. Simulations show that the incorporation of a specially designed Radio-Frequncy (RF) cavity into the UED apparatus removes this technical limitation. The RF cavity reverses the near linear position-momentum distribution of the temporally broadened electron bunch, causing the bunch to recompress itself as it propagates. It is found that our proposed method allows for sub-100 fs bunches with maximum charge of 0.6 pC, almost 3 orders of magnitude improvement over today's state of the art. Radio frequency. Cavity resonators. Electrons -- Diffraction. Picosecond pulses. Laser pulses, Ultrashort.
515	TWO-DIMENSIONAL SIMULATION OF SOLIDIFICATION IN FLOW FIELD USING PHASE-FIELD MODEL\|MULTISCALE METHOD IMPLEMENTATION Xu, Ying 01 January 2006 (has links) Numerous efforts have contributed to the study of phase-change problems for over a century\|both analytical and numerical. Among those numerical approximations applied to solve phase-transition problems, phase-field models attract more and more attention because they not only capture two important effects, surface tension and supercooling, but also enable explicitly labeling the solid and liquid phases and the position of the interface. In the research of this dissertation, a phase-field model has been employed to simulate 2-D dendrite growth of pure nickel without a flow, and 2-D ice crystal growth in a high-Reynolds-number lid-driven-cavity flow. In order to obtain the details of ice crystal structures as well as the flow field behavior during freezing for the latter simulation, it is necessary to solve the phase-field model without convection and the equations of motion on two different scales. To accomplish this, a heterogeneous multiscale method is implemented for the phase-field model with convection such that the phase-field model is simulated on a microscopic scale and the equations of motion are solved on a macroscopic scale. Simulations of 2-D dendrite growth of pure nickel provide the validation of the phase-field model and the study of dendrite growth under different conditions, e.g., degree of supercooling, interface thickness, kinetic coefficient, and shape of the initial seed. In addition, simulations of freezing in a lid-driven-cavity flow indicate that the flow field has great effect on the small-scale dendrite structure and the flow eld behavior on the large scale is altered by freezing inside it.
516	INVESTIGATION OF FILTERING METHODS FOR LARGE-EDDY SIMULATION Liu, Weiyun 01 January 2014 (has links) This thesis focuses on the phenomenon of aliasing and its mitigation with two explicit filters, i.e., Shuman and Padé filters. The Shuman filter is applied to velocity components of the Navier--Stokes equations. A derivation of this filter is presented as an approximation of a 1-D “pure math” mollifier and extend this to 2D and 3D. Analysis of the truncation error and wavenumber response is conducted with a range of grid spacings, Reynolds numbers and the filter parameter, β. Plots of the relationship between optimal filter parameter β and grid spacing, L2-norm error and Reynolds number to suggest ways to predict β are also presented. In order to guarantee that the optimal β is obtained under various stationary flow conditions, the power spectral density analysis of velocity components to unequivocally identify steady, periodic and quasi-periodic behaviours in a range of Reynolds numbers between 100 and 2000 are constructed. Parameters in Pade filters need not be changed. The two filters are applied to velocities in this paper on perturbed sine waves and a lid-driven cavity. Comparison is based on execution time, error and experimental results. Implicit filters explicit filters Shuman filters Pade filters lid-driven cavity Other Mechanical Engineering
517	Die Anwendung der Akustischen Rhinometrie beim Hund in der klinischen Veterinärmedizin Nather, Stephanie 03 June 2014 (has links) (PDF) Die akustische Rhinometrie ist in der Humanmedizin eine etablierte, nicht-invasive Methode zur Bestimmung von Nasenhöhlenvolumina und definierten Querschnittsflächen in nasalen Atemwegen beim Menschen. Sie basiert auf dem Vergleich beziehungsweise der Analyse der Amplituden von Schallwellen (definiert über die Querschnittsflächen) als Funktion der Zeit (definiert durch den Abstand in die Nasenhöhle), die durch Reflexionen einer Ausgangs-schallwelle in der Nasenhöhle entstehen. Das Ziel dieser Studie war es, erstmals den Nutzen der akustischen Rhinometrie für die klinische Veterinärmedizin bei Hunden zu überprüfen. Die Hauptschwerpunkte lagen in der Quantifizierung des geometrischen Aufbaus der Nasenhöhle von gesunden (n=15) und kranken (n=32) Hunden über die Auswertung der Flächenabstandskurven, der Definition von minimalen Querschnittsflächen (MCA1, MCA2) und Zuordnung zu anatomischen Landmarken auf CT-Schnittbildern. Für die Messungen wurde das Rhinometer SRE 2000 (RhinoMetrics, Dänemark) verwendet. Voruntersuchungen zu Wiederholbarkeit und Genauigkeit der Messmethode erfolgten an zylindrischen Stufenmodellen (n=3). Für jeden Beagle konnte eine deutliche Korrelation der ersten minimalen Querschnittsflächen zur Spitze der Concha nasalis ventralis nachgewiesen werden. Die zweite minimale Querschnittsfläche ließ sich keiner anatomischen Landmarke zuordnen. Es bestand kein statistisch signifikanter Unterschied in Nasenhöhlenvolumina, Auftreten der MCA1 und MCA2 und ihrer entsprechenden Dimension der jeweils rechten und linken Nasenhöhle im Gruppenvergleich. Nach lokaler Applikation von Xylometazolin lag die Größenzunahme des Volumens der rechten Nasen-höhle bei 19,4% [3,9-24,7%] (n=13) und der Linken bei 23,7% [15,4-36,4%] (n=12). Von insgesamt 32 untersuchten Hunden zeigten acht Hunde eindeutig einseitige Veränderungen (25%) in den CT-Schnittbildern. Anhand der Kurvensymmetrie ließ sich die pathologisch veränderte Nasenhöhlenseite nur in vier von acht Fällen zweifellos zuordnen. Besonders bei Erkrankungen mit Rhinorrhoe oder Ansammlungen von Sekret innerhalb der Nasenhöhle kam zu Fehlinterpretationen der Flächenabstandskurven. Oszillationen traten bei 22% der Patienten auf. Die Ergebnisse lassen Rückschlüsse zu, dass sich die akustische Rhinometrie aufgrund einer guten Wiederholbarkeit und einfachen Anwendung für wissenschaftliche Studien eignet, bei denen der Schwerpunkt auf intraindividuellen Vergleichen liegt. Obwohl die Daten objektiv ermittelt werden, ist die Anwendung dieser Methode in der klinischen Veterinärmedizin bei Hunden nur in Kombination mit anderen Untersuchungsmodalitäten sinnvoll. Fehlmessungen treten bereits bei einfach strukturierten Modellen auf; am caninen Patienten nehmen sie durch die ansteigende Diskrepanz zum idealen theoretischen Modell weiter zu. Primäre pathologische Veränderungen in der Nasenhöhlengeometrie werden nicht erkannt oder durch sekundäre Veränderungen maskiert. Verschiedene Krankheitsbilder weisen gleiche oder ähnliche strukturelle Veränderungen in der Nasenhöhle auf und können durch Messungen mit akustischen Schallwellen nicht unterschieden werden. Die Interpretation von Absolutwer-ten ist kritisch. Die Quantifizierung einer intranasalen Stenose ist nicht möglich. Akustische Rhinometrie Nasenhöhle Pulsreflektometrie Stenose acoustic rhinometry nasal cavity pulsreflectometry stenosis ddc:636.089
518	Basis Functions With Divergence Constraints for the Finite Element Method Pinciuc, Christopher 19 December 2012 (has links) Maxwell's equations are a system of partial differential equations of vector fields. Imposing the constitutive relations for material properties yields equations for the curl and divergence of the electric and magnetic fields. The curl and divergence equations must be solved simultaneously, which is not the same as solving three separate scalar problems in each component of the vector field. This thesis describes a new method for solving partial differential equations of vector fields using the finite element method. New basis functions are used to solve the curl equation while allowing the divergence to be set as a constraint. The basis functions are defined on a mesh of bricks and the method is applicable for geometries that conform to a Cartesian coordinate system. The basis functions are a combination of cubic Hermite splines and second order Lagrange interpolation polynomials. The method yields a linearly independent set of constraints for the divergence, which is modelled to second order accuracy within each brick. Mesh refinement is accomplished by dividing selected bricks into $2\times 2\times 2$ smaller bricks of equal size. The change in the node pattern at an interface where mesh refinement occurs necessitates a modified implementation of the divergence constraints as well as additional constraints for hanging nodes. The mesh can be refined to an arbitrary number of levels. The basis functions can exactly model the discontinuity in the normal component of the field at a planar interface. The method is modified to solve problems with singularities at material boundaries that form $90^{\circ}$ edges and corners. The primary test problem of the new basis functions is to obtain the resonant frequencies and fields of three-dimensional cavities. The new basis functions can resolve physical solutions and non-physical, spurious modes. The eigenvalues obtained with the new method are in good agreement with exact solutions and experimental values in cases where they exist. There is also good agreement with results from second-order edge elements that are obtained with the software package HFSS. Finally, the method is modified to solve problems in cylindrical coordinates provided the domain does not contain the coordinate axis. finite element method computational electromagnetics basis functions spurious modes resonant cavity 0544 0405 0607
519	Basis Functions With Divergence Constraints for the Finite Element Method Pinciuc, Christopher 19 December 2012 (has links) Maxwell's equations are a system of partial differential equations of vector fields. Imposing the constitutive relations for material properties yields equations for the curl and divergence of the electric and magnetic fields. The curl and divergence equations must be solved simultaneously, which is not the same as solving three separate scalar problems in each component of the vector field. This thesis describes a new method for solving partial differential equations of vector fields using the finite element method. New basis functions are used to solve the curl equation while allowing the divergence to be set as a constraint. The basis functions are defined on a mesh of bricks and the method is applicable for geometries that conform to a Cartesian coordinate system. The basis functions are a combination of cubic Hermite splines and second order Lagrange interpolation polynomials. The method yields a linearly independent set of constraints for the divergence, which is modelled to second order accuracy within each brick. Mesh refinement is accomplished by dividing selected bricks into $2\times 2\times 2$ smaller bricks of equal size. The change in the node pattern at an interface where mesh refinement occurs necessitates a modified implementation of the divergence constraints as well as additional constraints for hanging nodes. The mesh can be refined to an arbitrary number of levels. The basis functions can exactly model the discontinuity in the normal component of the field at a planar interface. The method is modified to solve problems with singularities at material boundaries that form $90^{\circ}$ edges and corners. The primary test problem of the new basis functions is to obtain the resonant frequencies and fields of three-dimensional cavities. The new basis functions can resolve physical solutions and non-physical, spurious modes. The eigenvalues obtained with the new method are in good agreement with exact solutions and experimental values in cases where they exist. There is also good agreement with results from second-order edge elements that are obtained with the software package HFSS. Finally, the method is modified to solve problems in cylindrical coordinates provided the domain does not contain the coordinate axis. finite element method computational electromagnetics basis functions spurious modes resonant cavity 0544 0405 0607
520	Nasal airway nitric oxide : methodological aspects and influence of inflammation / Palm, Jörgen, January 2004 (has links) Diss. (sammanfattning) Stockholm : Karol inst., 2004. / Härtill 5 uppsatser.

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