Global ETD Search

41	Effects Of Spin Polarization And Spatial Confinement On Optical Properties Of Bulk Semiconductors And Doped Quantum Wells Joshua, Arjun 02 1900 (has links) We correlated experimental results with theoretical estimations of the dielectric function ε(ω) in two contexts: the effect of an electric ﬁeld in quantum wells and that of the spin polarization of an interacting electron-hole plasma in bulk semiconductors. In the ﬁrst part, we recorded photoreﬂectance spectra from Ge/GeSi quantum wells of different widths but having comparable builtin electric ﬁelds caused by doping. The reason why the spectra differed in overall shape was difﬁcult to understand by conventional methods, for example, by calculating the allowed transition energies or by ﬁtting the data with lineshape functions at each transition energy. Instead, we computed the photoreﬂectance spectra from ﬁrst-principles by using the conﬁned electron and hole wavefunctions. This method showed that the spectra differ in overall shape because of the experimentally hitherto unobserved trend in quantum well electro-optical properties, from the quantum conﬁned Franz-Keldysh effect to the bulk Franz-Keldysh effect, as the well width is increased. The second part develops a threeband microscopic theory for the optical properties due to spin-polarized carriers in quasiequilibrium. We show that calculations based on this theory reproduce all the trends observed in a recent circularly polarized pump-probe experiment reported in the literature. To make the computation less intensive, we proposed a simpliﬁed, two-band version of this theory which captured the main experimental features. Besides, we constructed a cw diode laser-based pump-probe setup for our own optical studies of spin-polarized carriers by Kerr rotation. We achieved a sensitivity of detection of Kerr rotation of 3 x 10¯ 8 rad, corresponding to an order of magnitude improvement over the best reports in the literature. The efﬁcacy of our setup allowed for the demonstration of a pumpinduced spin polarization in bulk GaAs, under the unfavorable conditions of steady-state and room temperature. Spin Polarization Semiconductors Doped Quantum Well Spin-Polarized Semiconductors Kerr Rotation GaAs Allan Variance Electrodynamics
42	A measurement of the quark polarisation of the nucleon McAndrew, Michael Gabriel January 1999 (has links) No description available. 539.72
43	Štěrbinová anténa / Slot antenna Dvořák, Petr January 2014 (has links) This thesis discusses Slot antennas that are based in gap waveguide technology, which allows them to work with high frequency signals. It contains theoretical findings about antennas and waveguides, which are later used in the design. The practical section of this thesis concentrates on designing a specific gap waveguide for 10 and 24 GHz frequencies, starting with modeling and parameter optimalization. This gap waveguide is then used as a base for slot antenna design. The final antenna is designed for frequency of 10 GHz, for both linear and right-handed circular polarizations. With right-handed circular polarization, the achieved band was approximately 1.41 GHz, while the gain was 7,6 dB.
44	Study of Pion Photo-Production Using a TPC Detector to Determine Beam Asymmetries from Polarized HD Kizilgul, Serdar A. 22 July 2008 (has links) No description available. Experiments Nuclear Physics double polarization time projection chamber neutron observables from deuteron beam asymmetry track reconstruction software LEGS collaboration polarized gamma ray beam polarized HD target
45	Thin Films for the Transport of Polarized Ultracold Neutrons for Fundamental Symmetry Study Mammei, Russell Rene 24 August 2010 (has links) The use of ultracold neutrons (UCN) to study fundamental parameters such as the neutron lifetime and decay correlations in polarized neutron beta decay are poised to make significant contributions to our understand of the Standard Model and its extensions. To this end, the UCNA experiment is pursuing a precision measurement (0.2%) of the angular correlation between the neutron spin and the direction of emission of the electron in polarized neutron decay (the ``A'' asymmetry). The UCNA experiment makes use of the spallation-driven solid deuterium (SD2) UCN source at the Los Alamos Neutron Science Center (LANSCE). The UCN leave the source and are 100% polarized by passing through a strong magnetic field before their decay is observed by a very sensitive electron spectrometer. UCN guides facilitate the transfer of UCN from the source to the spectrometer. Common guide materials include stainless steel, copper, aluminum, and quartz. Often a thin film is applied to these components to increase their ability to transport/bottle and preserve the polarization of UCN. In the region of the SD2 UCN source, nickel-58 films are applied, whereas once the UCN are polarized, diamond-like carbon (DLC) films are employed. This dissertation covers the application, process developments, and characterization of these coatings. In addition a study concerning the surface finish resulting from the mechanical polishing and electropolishing of the guides that make up the UCNA beamline is presented. / Ph. D. Neutron Beta Decay Polarized Ultracold Neutrons Standard Model Tests Diamond-Like Carbon Polarized Neutron Guides Pulsed Laser Deposition Ebeam Evaporation Electropolishing Mechanical Polishing Surface Roughness
46	NORMAL AND SPIN POLARIZED TRANSPORT IN HIGH-TEMPERATURE SUPERCONDUCTOR TUNNELING JUNCTIONS Freamat, Mario Vadim 01 January 2004 (has links) One of the challenges facing condensed matter physics nowadays is to understand the electronic structure of high temperature superconductors. This dissertation compiles our contribution to the experimental information concerning this subject. Tunneling conductance spectroscopy a technique capable of probing the electronic density of states in hybrid structures was used to study the current and spin transport properties across junctions between metallic counterelectrodes and Bi2Sr2CaCu2O8- (BSCCO) crystals. Since in these structures the transport is mediated by transmission channels depending on superconductive characteristics, the energy resolved density of states is a signature of the mechanism of superconductivity. For instance, one can observe the superconductive energy gap and the behavior of subgap bound states due to phase sensitive Andreev reflections at the junction interface. In particular, tunneling spectroscopy makes possible the observation of the LOFF state characterized by the coexistence of superconductivity and magnetism. Cuprates like BSCCO are highly anisotropic materials and their superconductivity is almost two dimensional, being confined in the CuO2 planes. Therefore, our junctions combine monocrystals of underdoped samples of BSCCO with various thin film counterelectrodes normal metal (Ag), conventional superconductor (Pb) and ferromagnetic metal (Fe) deposited perpendicular onto the cuprate ab-plane (CuO2 plane). We performed measurements on Ag/BSCCO junctions for two current injection directions into the same crystal. We observed that, near the 110 crystal surface, the conductance spectra show a high zero bias peak (ZBCP) which is a manifestation of zero energy Andreev bound states due to an anisotropic superconductive order parameter. Near the 100 surface, the ZBCP is largely suppressed. This is consistent with a predominantly 2 2 x y d - -wave pairing symmetry. In some cases, the ZBCP splits or decreases in amplitude at low temperatures. This is consistent with the existence of a subdominant s-wave (or xy d ) resulting in a mixed d is + state which breaks time reversal symmetry (BTRS). Since we observe this phenomenon in the underdoped case, we do not confirm the possibility of a quantum critical point close to the optimal doping. Our Pb/BSCCO spectra contradict the theory explaining the BTRS by proximity effect. The Fe/BSCCO junctions measure the effect of spin polarization. We explain the recorded 4-peak asymmetric structure by the combined effect of a spin independent BTRS state and a spin filtering exchange energy in the barrier responsible for a large ZBCP splitting. The LOFF state was observed in the proximity region induced on the ferromagnetic side of multilayered-Fe/Ag/BSCCO structures. As expected for the LOFF order parameter, the spectra develops coherent damped oscillations with the Fe layer thickness probing different regions. The magnitude and sign of the oscillation depends on the energy. The conductances at energy zero or equal to the superconductive gap are modulated in antiphase proving that the order parameters takes successively positive and negative values. Changing the junction orientation with 4 p , results in an opposite behavior for the same distance. The maximal amplitudes in one direction is replaced by minima, showing that, besides space, the LOFF state modulation depends on the phase of the high temperature order parameter inducing the proximity
47	ANISOTROPIC POLARIZED LIGHT SCATTER AND MOLECULAR FACTOR COMPUTING IN PHARMACEUTICAL CLEANING VALIDATION AND BIOMEDICAL SPECTROSCOPY Urbas, Aaron Andrew 01 January 2007 (has links) Spectroscopy and other optical methods can often be employed with limited or no sample preparation, making them well suited for in situ and in vivo analysis. This dissertation focuses on the use of a near-infrared spectroscopy (NIRS) and polarized light scatter for two such applications: the assessment of cardiovascular disease, and the validation of cleaning processes for pharmaceutical equipment.There is a need for more effective in vivo techniques for assessing intravascular disorders, such as aortic aneurysms and vulnerable atherosclerotic plaques. These, and other cardiovascular disorders, are often associated with structural remodeling of vascular walls. NIRS has previously been demonstrated as an effective technique for the analysis of intact biological samples. In this research, traditional NIRS is used in the analysis of aortic tissue samples from a murine knockout model that develops abdominal aortic aneurysms (AAAs) following infusion of angiotensin II. Effective application of NIRS in vivo, however, requires a departure from traditional instrumental principles. Toward this end, the groundwork for a fiber optic-based catheter system employing a novel optical encoding technique, termed molecular factor computing (MFC), was developed for differentiating cholesterol, collagen and elastin through intervening red blood cell solutions. In MFC, the transmission spectra of chemical compounds are used to collect measurements directly correlated to the desired sample information.Pharmaceutical cleaning validation is another field that can greatly benefit from novel analytical methods. Conventionally cleaning validation is accomplished through surface residue sampling followed by analysis using a traditional analytical method. Drawbacks to this approach include cost, analysis time, and uncertainties associated with the sampling and extraction methods. This research explores the development of in situ cleaning validation methods to eliminate these issues. The use of light scatter and polarization was investigated for the detection and quantification of surface residues. Although effective, the ability to discriminate between residues was not established with these techniques. With that aim in mind, the differentiation of surface residues using NIRS and MFC was also investigated.
48	Patterned Liquid Crystal Polymer Retarders, Polarizers, and Sources Myhre, Graham January 2012 (has links) Liquid crystals are traditionally aligned via a rubbed substrate. The rubbing creates anisotropic defects and strain in the material which provide an energetically favorable orientation for the liquid crystal (LC). This is a well-developed technology that is used in virtually all liquid crystal displays (LCDs). However, it is only capable of uniform alignment on a large planar substrate. This work utilizes a new class of photoalignment materials (PM) that replace the traditional buffing technique. PMs allow for patterned LC alignment using polarized photo-lithography. Further, instead of using a nematic liquid crystal, a UV curable liquid crystal polymer (LCP) is coated on this patterned alignment material. This generates a cured, aligned, and patterned thin film that has retardance and diattenuation if a dichroic dye is incorporated in the LCP. Using these materials and methods, retarders, polarizers, and polarized fluorescent sources are fabricated with dimensions as small as a few microns. In addition to exploring the material and processing properties of the PM and LCP system, arrays of micropolarizer are fabricated for the construction of a prototype polarization camera, termed an imaging polarimeter. An imaging polarimeter is a device that measures not only the intensity but also the polarization state of a light field. My imaging polarimeter design incorporates a patterned LCP polarizer focal plane array (FPA) that is aligned and mounted to a charge-couple-device (CCD) image sensor. A polarizer FPA allows an individual pixel on a CCD sensor to detect a unique polarization state, such as a specific linear polarization orientation or right or left handed circular polarization. Neighboring pixels are designed to detect different states and each cluster can then estimate the incident polarization state. Results of a linear LCP polarimeter operating in the visible spectrum are presented. Liquid Crystal Photo Alignment Polarimeter Polarized Fluorescence Optical Sciences Dichroic Dye Focal Plane Array
49	Visualizing Protein Interactions at Supported Bilayer Surfaces Vanderlee, Gillian 10 December 2013 (has links) Understanding the mechanisms by which proteins act on membrane surfaces is fundamental if we are to exploit their capabilities or halt the progression of the diseases they are associated with. Arguably, the best way to study these interactions is by using techniques that can obtain molecular-scale information, in real time and under physiologically relevant conditions. Studying supported lipid bilayer systems with high spatial resolution tools, such as atomic force microscopy (AFM), and high temporal resolution techniques, such as polarized total internal reflection fluorescence microscopy (pTIRFM), allows us to meet these requirements [1]. The goal of this project is to use methods that are currently available and further their applications and capabilities to provide insight into the mechanisms by which amyloidogenic and antimicrobial peptides act on membranes. atomic force microscopy antimicrobial amyloid bilayer order parameter 0541
50	Visualizing Protein Interactions at Supported Bilayer Surfaces Vanderlee, Gillian 10 December 2013 (has links) Understanding the mechanisms by which proteins act on membrane surfaces is fundamental if we are to exploit their capabilities or halt the progression of the diseases they are associated with. Arguably, the best way to study these interactions is by using techniques that can obtain molecular-scale information, in real time and under physiologically relevant conditions. Studying supported lipid bilayer systems with high spatial resolution tools, such as atomic force microscopy (AFM), and high temporal resolution techniques, such as polarized total internal reflection fluorescence microscopy (pTIRFM), allows us to meet these requirements [1]. The goal of this project is to use methods that are currently available and further their applications and capabilities to provide insight into the mechanisms by which amyloidogenic and antimicrobial peptides act on membranes. atomic force microscopy antimicrobial amyloid bilayer order parameter 0541

Search results