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611	Vector finite element methods for spurious-free solutions of unbounded dielectric and ferrite loaded waveguiding structures Crain, Bruce Richard 05 1900 (has links) No description available. Ferrites (Magnetic materials) Wave guides Mathematical models Finite element method
612	BiSI ir BiSeI kristalų elektroninės struktūros ir optinių savybių tyrimas / An investigation of electronic structure and optical properties of BiSI and BiSeI crystals Liutkevič, Svetlana 27 June 2011 (has links) Šio darbo tikslas ištirti BiSI ir BiSeI kristalų optines savybes ir palyginti teorines optinių dielektrinių funkcijų priklausomybes nuo fotono energijos, nuo 0 iki 25 eV energijos srityje. BiSI ir BiSeI kristalų elektroninė struktūra buvo tirta FP-LAPW metodu, naudojant tankio funkcionalo teorija (DFT) ir „Wien2k“ kompiuterinę programą. Eksperimentiniai BiSI ir BiSeI kristalų dielektrinių funkcijų spektrai menamosios ir realiosios dalies buvo gauti naudojant elipsinių parametrų spektrus išmatuotus su optiniu elipsometru spektro srityje nuo 1 iki 5,5 eV. Eksperimentiniai dielektrinių funkcijų spektrai menamosios ir realiosios dalies buvo analizuoti su keturiais Lorenco osciliatoriais naudojant pseudo dielektrinių funkcijų (PDF) metodą. / In this work electronic structure of the valence band and optical properties of the semiconducting BiSI and BiSeI crystals are investigated in the energy range 0 – 25 eV. Calculations were made with ab initio based on the density-functional theory (DFT) with program Wien2k. The full potential linearized augmented plane wave (FP-LAPW) method was used with the generalized gradient approximation (GGA).Dielectric functions imaginary and real parts of BiSI and BiSeI crystals agree satisfactory with corresponding experimental dependences obtained by spectroscopic ellipsometry technique in the spectral range of 1 – 5.5 eV. Experimentally investigated imaginary and real parts spectra have been described by contribution of four Lorentz – type lines in the model of pseudo-dielectric function (PDF). Physics BiSI BiSeI Lorenco osciliatoriai Dielektrinis spektras BiSI BiSeI Lorentz – type line Dielectric spectra
613	Active Surfaces and Interfaces of Soft Materials Wang, Qiming January 2014 (has links) <p>A variety of intriguing surface patterns have been observed on developing natural systems, ranging from corrugated surface of white blood cells at nanometer scales to wrinkled dog skins at millimeter scales. To mimetically harness functionalities of natural morphologies, artificial transformative skin systems by using soft active materials have been rationally designed to generate versatile patterns for a variety of engineering applications. The study of the mechanics and design of these dynamic surface patterns on soft active materials are both physically interesting and technologically important. </p><p>This dissertation starts with studying abundant surface patterns in Nature by constructing a unified phase diagram of surface instabilities on soft materials with minimum numbers of physical parameters. Guided by this integrated phase diagram, an electroactive system is designed to investigate a variety of electrically-induced surface instabilities of elastomers, including electro-creasing, electro-cratering, electro-wrinkling and electro-cavitation. Combing experimental, theoretical and computational methods, the initiation, evolution and transition of these instabilities are analyzed. To apply these dynamic surface instabilities to serving engineering and biology, new techniques of Dynamic Electrostatic Lithography and electroactive anti-biofouling are demonstrated.</p> / Dissertation Mechanics Materials Science Polymer chemistry Dielectric elastomer electrostatic lithography Soft active materials Surface instability surface patterning
614	Design, Analysis, And Characterization Of Metamaterial Quasi-Optical Components For Millimeter-Wave Automotive Radar Nguyen, Vinh Ngoc January 2013 (has links) <p>Since their introduction by Mercedes Benz in the late 1990s, W-band radars operating at 76-77 GHz have found their way into more and more passenger cars. These automotive radars are typically used in adaptive cruise control, pre-collision sensing, and other driver assistance systems. While these systems are usually only about the size of two stacked cigarette packs, system size, and weight remains a concern for many automotive manufacturers.</p><p>In this dissertation, I discuss how artificially structured metamaterials can be used to improve lens-based automotive radar systems. Metamaterials allow the fabrication of smaller and lighter systems, while still meeting the frequency, high gain, and cost requirements of this application. In particular, I focus on the development of planar artificial dielectric lenses suitable for use in place of the injection-molded lenses now used in many automotive radar systems.</p><p>I begin by using analytic and numerical ray-tracing to compare the performance of planar metamaterial GRIN lenses to equivalent aspheric refractive lenses. I do this to determine whether metamaterials are best employed in GRIN or refractive automotive radar lenses. Through this study I find that planar GRIN lenses with the large refractive index ranges enabled by metamaterials have approximately optically equivalent performance to equivalent refractive lenses for fields of view approaching ±20°. I also find that the uniaxial nature of most planar metamaterials does not negatively impact planar GRIN lens performance.</p><p>I then turn my attention to implementing these planar GRIN lenses at W-band automotive radar frequencies. I begin by designing uniform sheets of W-band electrically-coupled LC resonator-based metamaterials. These metamaterial samples were fabricated by the Jokerst research group on glass and liquid crystal polymer (LCP) substrates and tested at Toyota Research Institute- North America (TRI-NA). When characterized at W-band frequencies, these metamaterials show material properties closely matching those predicted by full-wave simulations.</p><p>Due to the high losses associated with resonant metamaterials, I shift my focus to non-resonant metamaterials. I discuss the design, fabrication, and testing of non-resonant metamaterials for fabrication on multilayer LCP printed circuit boards (PCBs). I then use these non-resonant metamaterials in a W-band planar metamaterial GRIN lens. Radiation pattern measurements show that this lens functions as a strong collimating element.</p><p>Using similar lens design methods, I design a metamaterial GRIN lens from polytetrafluoroethylene-based (PTFE-based) non-resonant metamaterials. This GRIN lens is designed to match a target dielectric lens's radiation characteristics across a ±6° field of view. Measurements at automotive radar frequencies show that this lens has approximately the same radiation characteristics as the target lens across the desired field of view.</p><p>Finally, I describe the development of electrically reconfigurable metamaterials using thin-film silicon semiconductors. These silicon-based reconfigurable metamaterials were developed in close collaboration with several other researchers. My major contribution to the development of these reconfigurable metamaterials consisted of the initial metamaterial design. The Jokerst research group fabricated this initial design while TRI-NA characterized the fabricated metamaterial experimentally. Measurements showed approximately 8% variation in transmission under a 5 Volt DC bias. This variation in transmission closely matched the variation in transmission predicted by coupled electronic-electromagnetic simulation run by Yaroslav Urzhumov, one of other contributors to the development of the reconfigurable metamaterial.</p> / Dissertation Electromagnetics Electrical engineering Optics Artificial Dielectric Automotive Radar Lens Metamaterials Millimeter-Wave Quasioptics
615	A Digital Microfluidic Platform for Human Plasma Protein Depletion Mei, NINGSI 29 May 2014 (has links) Digital microfluidics (DMF) is an emerging liquid-handling technique that facilitates manipulation of discrete droplets across an array of electrodes. Although the working principle of droplet movement is still under debate, it has gained significant interest as the technique has been applied to various applications in biology, chemistry and medicine. With recent advances in rapid prototyping and multilayer fabrication techniques using printed circuit boards, DMF has become an attractive and alternative solution to conventional macroscale fluidics techniques with additional capability of sample size reduction, faster analysis time, full automation, and multiplexing. In this thesis, we explore the use of DMF for human plasma protein depletion due to its multiple advantages. The high abundance of human serum albumin (HSA) and immunoglobulins (Igs), which constitute 80% of total plasma proteins, is a major challenge in proteome studies. Unfortunately, conventional methods to deplete high abundant proteins (e.g. macro LC-columns) are labour-intensive, require dilution of sample, and run the risk of sample loss. Furthermore, most techniques lack the ability to process multiple samples simultaneously. Hence, we developed a new method of protein depletion using anti-HSA and Protein A/G immobilized paramagnetic beads manipulated by DMF to deplete HSA and IgG from human plasma. Toward this goal, prototype DMF devices and electronic controller were designed, built and characterized (Chapter 2). Preliminary depletion experiments were first optimized in-tubes and then adapted for DMF manually (Chapter 3). At last, the entire depletion process was performed on DMF using an automated controller system (Chapter 4). Results showed that the protein depletion efficiency for immunoglobulin G (IgG) and HSA in 10 minutes for four samples simultaneously was as high as 98%, and an approximately 3-fold increase in signal-to-noise ratio after depletion was demonstrated by MALDI-MS analysis. The depletion process is sufficient for a tryptic digest to be performed on a model protein, cytochrome C, where 89% sequence coverage was obtained for a depleted sample. Although some improvements such as on-chip sample processing (e.g. digestion) need to be carried out as future work, we anticipate that the new technique is a significant alternative for applications involving protein depletion steps. / Thesis (Master, Chemistry) -- Queen's University, 2014-05-29 02:38:50.176 Mass Spectrometry Digital Microfluidics Magnetic Separation Electrowetting-on-dielectric (EWOD) Protein Depletion
616	Reconfigurable Dielectric Resonator Antennas Desjardins, Jason 21 March 2011 (has links) With the increasing demand for high performance communication networks and the proliferation of mobile devices, significant advances in antenna design are essential. In recent years the rising demands of the mobile wireless communication industry have forced antennas to have increased performance while being limited to an ever decreasing footprint. Such design constraints have forced antenna designers to consider frequency agile antennas so that their behavior can adapt with changing system requirements or environmental conditions. Frequency agile antennas used for mobile handset applications must also be inexpensive, robust, and make use of electronic switching with reasonable DC power consumption. Previous works have addressed a number of these requirements but relatively little work has been performed on frequency agile dielectric resonator antennas (DRAs). The objective of this thesis is to investigate the use of DRAs for frequency reconfigurability. DRAs are an attractive option due to their compactness, very low losses leading to high radiation efficiencies (better than 95%) and fairly wide bandwidths compared to alternatives. DRA’s are also well suited for mobile communications since they can be placed on a ground plane and are by nature low gain antennas whose radiation patterns typically resemble those of short electric or magnetic dipoles. One way to electronically reconfigure a DRA, in the sense of altering the frequency band over which the input reflection coefficient of the antenna is below some threshold, is to partially load one face of the DRA with a conducting surface. By altering the way in which this surface connects to the groundplane on which the DRA is mounted, the DRA can be reconfigured due to changes in its mode structure. This connection was first made using several conducting tabs which resulted in a tuning range of 69% while having poor cross polarization performance. In order to address the poor cross polarization performance a second conducting surface was placed on the opposing DRA wall. This technique significantly reduced the cross polarization levels while obtaining a tuning range of 83%. The dual-wall conductively loaded DRA was then extended to include a full electronic implementation using PIN diodes and varactor diodes in order to achieve discrete and continuous tuning respectively. The two techniques both achieved discrete tuning ranges of 95% while the varactor implementation also had a continuous tuning range of 59% while both maintaining an acceptable cross polarization level. Antenna Continuous Tuning Dielectric Resonator Antenna Electrically Small Antenna Frequency Agile Multiband Antenna
617	Periodic Mesoporous Organosilica and Silica Wang, Wendong 31 August 2011 (has links) Periodic mesoporous material is a class of solids that possess periodically ordered pores with sizes of 2–50 nm. After a brief introduction to the synthesis, structure, property and function of periodic mesoporous materials in general in Chapter 1, a specific type of periodic mesoporous material, periodic mesoporous organosilica (PMO), is examined in detail in Chapter 2. Chapter 3 and Chapter 4 focus on the application of periodic mesoporous organosilica as low-dielectric-constant (low-k) insulating materials on semiconductor microprocessors. Specifically, Chapter 3 introduces a vapor-phase delivery technique, vacuum-assisted aerosol deposition, for the synthesis of PMO thin films; Chapter 4 studies one property crucial for the application of low-k PMO in detail—hydrophobicity. The focus of Chapter 5 turns to a novel sandwich-structured nanocomposite made of periodic mesoporous silica and graphene oxide. In Chapter 6, progress towards the synthesis of periodic mesoporous quartz is summarized. A conclusion and an outlook are given in Chapter 7. Porous Materials thin films Low dielectric constant inorganic-organic hybrid 0488 0794
618	Modeling of and Driver Design for a Dielectric Barrier Discharge Lamp El-Deib, Amgad 12 August 2010 (has links) Dielectric Barrier Discharge (DBD) excimer lamp is a very attractive source for Ultraviolet (UV) radiation. It has a number of advantages compared to the mercury lamp which is the main lamp used in the industry for UV production. Some of these advantages are instant UV radiation (no warm-up period), narrow UV spectrum, longer life times and simple construction. The DBD UV lamp can be used in number of applications like water disinfection, Plasma Display Panels (PDP) and surface treatment in the semiconductor industry. Yet, the full industrial application of this lamp still faces some problems mainly related to finding the optimum electrical driver to maximize the efficiency of such a lamp. This includes the type of the electrical waveform to generate and the power electronic driver to produce it. In this thesis, firstly a physically based circuit model for the DBD lamp using the Finite Volume Method (FVM) is developed. This model provides the electrical and optical characteristics of the lamp. Using this model the sensitivity of the lamp efficiency to the proposed electrical waveform has been determined. Secondly, the order of this FVM model has been reduced to obtain a model which is used in the design procedure of the proposed driver. Since the DBD lamp has a capacitive nature, a current controlled driver is proposed in this thesis as opposed to most of the published drivers which are voltage controlled drivers. The design of this driver is intended to enhance the electrical to optical efficiency of the lamp and therefore enhancing the overall efficiency of the system. The driver topology permits direct control of the peak lamp current and the operating frequency of the supplied current to the DBD lamp. The width of the current pulses is determined by the transformer magnetizing inductance and the lamp capacitance. Experimental results of the proposed driver connected to a XeCl DBD lamp are presented to validate the performance of the driver and to prove the concept of such a current controlled driver. The proposed driver performance is compared to a voltage source driver which was also implemented. The proposed driver produced higher overall system efficiency but at the expense of a reduction in the driver efficiency as compared to the voltage source driver. The complete system, which consists of the developed FVM based model and the equivalent circuit of the proposed driver, was simulated and the results were compared to the experimental results to validate the accuracy of the developed model for the DBD lamp. Plasma Modeling Power Electronics Finite Volume Method Dielectric Barrier Discharge 0544
619	Periodic Mesoporous Organosilica and Silica Wang, Wendong 31 August 2011 (has links) Periodic mesoporous material is a class of solids that possess periodically ordered pores with sizes of 2–50 nm. After a brief introduction to the synthesis, structure, property and function of periodic mesoporous materials in general in Chapter 1, a specific type of periodic mesoporous material, periodic mesoporous organosilica (PMO), is examined in detail in Chapter 2. Chapter 3 and Chapter 4 focus on the application of periodic mesoporous organosilica as low-dielectric-constant (low-k) insulating materials on semiconductor microprocessors. Specifically, Chapter 3 introduces a vapor-phase delivery technique, vacuum-assisted aerosol deposition, for the synthesis of PMO thin films; Chapter 4 studies one property crucial for the application of low-k PMO in detail—hydrophobicity. The focus of Chapter 5 turns to a novel sandwich-structured nanocomposite made of periodic mesoporous silica and graphene oxide. In Chapter 6, progress towards the synthesis of periodic mesoporous quartz is summarized. A conclusion and an outlook are given in Chapter 7. Porous Materials thin films Low dielectric constant inorganic-organic hybrid 0488 0794
620	Analysis And Design Of Passive Microwave And Optical Devices Using The Multimode Interference Technique. Sunay, Ahmet Sertac 01 July 2005 (has links) (PDF) The Multimode Interference (MMI) mechanism is a powerful toool used in the analysis and design of a certain class of optical, microwave and millimeter wave devices. The principles of the MMI method and the self-imaging principle is described. Using this method, NXM MMI couplers, MMI splitter/combiners are analyzed. Computer simulations for illustrating the &quot / Multimode Interference Mechanism&quot / are carried out. The MMI approach is used to analyze overmoded &#039 / rectangular metallic&#039 / and &#039 / dielectric slab&#039 / type of waveguides and devices. The application of the MMI technique is investigated experimentally by using a metallic waveguide structure operating in the X-band. The construction of the related structure and the related experimental work are reported. TK Electronics 7800-8360

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