Global ETD Search

301	Lanthanide doped ceria thin films as possible counter electrode materials in electrochromic devices Hartridge, Adrian January 2000 (has links) No description available. 530.41
302	Structural properties of multi-layered materials Loader, Charlotte Bree January 2000 (has links) No description available. 669
303	Fundamental studies of growth mechanisms in physical vapour deposition of aluminium Knorr, Nicholas J. January 2000 (has links) No description available. 530.41
304	Crystalline structure, and magnetic and magneto-optical properties of MnSbBi thin films Kang, Kyongha January 2001 (has links) No description available. 530.41
305	Glass poly-vinyl-phosphonate cements with reactive aluminium hydroxide coated sub-micron anatase filler Brookbank, Paul Alexander January 2011 (has links) The current generation of Glass Ionomer Cements (GICs) have many advantageous properties over other dental restorative materials but lack the compressive strength of these other materials. The aim of this project is to increase the compressive strength of conventional Glass Poly-Vinyl-Phosphonate cement by inclusion of reactive sub-micron filler particles. The setting characteristics, chemical reactivity and cement strength have been found using oscillating rheology, infrared spectrometry, nuclear magnetic spectrometry, transmission electron microscopy, potentiometer analysis, laser diffractometry and mechanical analysis. The addition of sub-micron filler particles in direct weight by weight replacement of aluminosilicate glass of a control material has increased the ultimate compressive strength of the new cement from 206MPa (control) to 250MPa after 365 days of aging. The strength of the new filler enhanced cements were comparable with the control material after 3 hours. The setting chemistry of the filler enhanced cements follows the same order as the control cement but at a decelerated rate. Theoretical modelling found that a large volume of sub-micron filler could fit into interstitial spacing in formed cement however the alteration of the aluminosilicate glass to polyelectrolyte ratio has been found to drastically alter the cement setting time. The use of cubic and polyhedral shaped filler particles as supposed to spherical particles may increase the cement strength further as greater packing densities are achieved. The formulation of a Glass Ionomer Cement with increased compressive strength may find use as a posterior restorative or as a better material for restoration of lesions and cavity liners. 617.6
306	Growth and Characterization of Ti-Si-N Hard Coatings Flink, Axel January 2006 (has links) Metastable (Ti,Si)N alloy and TiN/SiNx multilayer thin solid films as well as SiNx/TiN surfaces have been explored. Cubic Ti1-xSixN (0≤x≤0.14) films deposited onto cemented carbide (WC-Co) substrates by arc evaporation exhibited a competitive columnar growth mode where the structure transforms to a feather-like nanostructure with increasing Si content as revealed by x-ray diffraction and transmission electron microscopy. X-ray photoelectron spectroscopy revealed the presence of Ti-N and Si-N bonding, but no amorphous Si3N4. Band structure calculations showed that phase separation of NaClstructure Ti1-xSixN solid solution into cubic SiN and TiN phases is energetically favorable. The metastable microstructure, however, was maintained for the Ti0.86Si0.14N film annealed at 900°C, while recrystallization in the cubic state took place at 1100°C annealing during 2h. The Si content influenced the film hardness close to linearly, by combination of solid-solution hardening in the cubic state and defect hardening. For x=0 and x=0.14, nanoindentation gave a hardness of 29.9±3.4 GPa and 44.7±1.9 GPa, respectively. The hardness was retained during annealing at 900°C. Nanostructured materials, e.g., nanocomposites and nanolaminates, are defined by internal interfaces, of which the nature is still under debate. In this work two-phase model systems were explored by depositing SiNx/TiN nanolaminate films, including superlattices containing cubic SiNx, by dual target reactive magnetron sputtering. It is demonstrated that the interfacial phase of SiNx onto TiN(001) and TiN(111) can be crystalline, and even epitaxial with complex surface reconstructions. Using in situ structural analyses combined with ab initio calculations, it is found that SiNx layers grow epitaxially, giving rise to strong interfacial bonding, on both TiN(001) and TiN(111) surfaces. In addition, TiN overlayers grow epitaxially on SiNx/TiN(001) bilayers in nanolaminate structures. These results provide insight into the development of design rules for novel nanostructured materials. / Report code: LiU-TEK-LIC-2006:51. Ti-Si-N physical vapor deposition nitrides density functional theory transmission electron microscopy nanocomposits nanolaminates solid solutions Material physics with surface physics Materialfysik med ytfysik
307	A study of irradiation damage in iron and Fe-Cr alloys Xu, Shuo January 2013 (has links) Irradiation damage structures induced in pure Fe and Fe-Cr (up to 14%Cr) alloys by 2 MeV Fe+ ion irradiations in the temperature range 300-460°C were investigated by transmission electron microscopy. Specimens were irradiated in bulk to doses of 1.5 x 1019 Fe+/m2 (about 2.5 displacements per atom: dpa) and 4.5 x 1019 Fe+/m2 (about 7 dpa). In most cases, damage took the form of dislocation loops with diameters from 2-100nm; the loops were distributed uniformly within all the samples. At higher irradiation temperatures (400°C, 460°C), complex microstructures such as finger loops (50nm in width and 1 micron in length) and perpendicular <100> loop clusters, were observed in both pure Fe and Fe-Cr samples. Loop sizes and densities were seen to change as a function of irradiation temperature and dose. Loop sizes were seen to increase as the increase of irradiation temperatures and doses, while loop densities only increased with increasing doses and decreased as increasing temperatures. Loops with both types of Burgers vectors (<100> and ½<111>) were observed in all the samples. The proportion of <100> loops was higher in Fe than that in Fe-Cr alloys at the same irradiation condition, which has can be attributed to the high mobility of ½<111> loops in Fe, so that a large proportion of them will escape to the (001) foil surface. A transition in loop Burgers vectors as a consequence of increasing temperature was observed. In Fe, the proportion of <100> loops increased with increasing irradiation temperature from 40% at 300°C to 60% at 460°C. A similar trend was found in the Fe-Cr alloys, but due to the higher proportion of ½<111> loops in these alloys, the increase of <100> loops was not that obvious, being from 30% at 300°C to 45% at 460°C(Fe-11Cr). The effects of irradiation dose rate on the formation of dislocation loops by 2 MeV Fe+ ions were also investigated. These irradiations were carried out at 300°C with two different implantation dose rates: 6 x 10-4 dpa/s and 3 x 10-5 dpa/s. The implantation dose for both implantations was 0.38 x 1019 Fe+/m2 (0.5 dpa). Both the average loop size and loop densities for the Fe-Cr specimens subjected to the high dose rate irradiation were higher than that in the low dose rate irradiations. Take Fe-14Cr as an example, that the loop densities in high dose rate irradiation increased about 90% compared to that in low dose rate, and the average loop size in high dose rate irradiation was 30% larger than that in low dose rate irradiation. The ‘inside-outside contrast’ method was applied to determine the loop nature in all the samples. It was found that all the large loops (>5nm) are of interstitial type. Any vacancies are believed to exist in the form of small dislocation loops (<5nm) or sub-microscopic voids. 620.1
308	Characterization and Mechanical Properties of Nanoscale Precipitates in Modified Al-Si-Cu Alloys Using Transmission Electron Microscopy and 3D Atom Probe Tomography. Hwang, Junyeon 05 1900 (has links) Among the commercial aluminum alloys, aluminum 319 (Al-7wt%Si-4wt%Cu) type alloys are popularly used in automobile engine parts. These alloys have good casting characteristics and excellent mechanical properties resulting from a suitable heat treatment. To get a high strength in the 319 type alloys, grain refining, reducing the porosity, solid solution hardening, and precipitation hardening are preferred. All experimental variables such as solidification condition, composition, and heat treatment are influence on the precipitation behavior; however, precipitation hardening is the most significant because excess alloying elements from supersaturated solid solution form fine particles which act as obstacles to dislocation movement. The challenges of the 319 type alloys arise due to small size of precipitate and complex aging response caused by multi components. It is important to determine the chemical composition, crystal structure, and orientation relationship as well as precipitate morphology in order to understand the precipitation behavior and strengthening mechanism. In this study, the mechanical properties and microstructure were investigated using transmission electron microscopy and three dimensional atom probe tomography. The Mn and Mg effects on the microstructure and mechanical properties are discussed with crystallographic study on the iron intermetallic phases. The microstructural evolution and nucleation study on the precipitates in the low-Si 319 type aluminum alloys are also presented with sample preparation and analysis condition of TEM and 3DAP tomography. Precipitation strengthening age hardening 319 Al alloy mechanical property transmission electron microscopy atom probe microstructural evolution Aluminum alloys -- Microstructure. Precipitation hardening.
309	Structural and optical characterization of SiC / Caractérisation structurale et optique de carbure silicium Zoulis, Georgios 24 February 2011 (has links) Ce travail porte sur la caractérisation structurale et optique d'échantillons de SiC. Les échantillons étudiés ont été répartis en trois groupes : des échantillons massifs, des couches épitaxiales épaisses et enfin des couches minces. La croissance des échantillons massifs a été réalisée avec la technique CF-PVT, utilisant une géométrie « d'étranglement ». L'objectif était de filtrer les défauts afin de créer des germes de 3C de haute pureté. La croissance de des couches épaisses par sublimation avait comme objectif la maitrise d'un dopage résiduel faible de type n et p pour des applications composants. Enfin, dans le but de réaliser des composants de type LED blanche des impuretés Ga ont été introduites dans des couches minces épitaxiées par VLS afin de créer des échantillons fortement dopé de type p. Tous ces échantillons ont été étudiés par photoluminescence, micro-Raman, SIMS et microscopie électronique à transmission. Il a été possible de déterminer la concentration d'impuretés et d'identifier le caractère n ou p de ces échantillons. L'analyse des échantillons a été faite en utilisant à la fois l'observation des défauts structurels et les informations obtenues à partir des techniques de caractérisation optique. Nous avons pu obtenir des informations sur les paramètres physiques de 3C-SiC, comme l'énergie de liaison de Ga et Al, la structure fine des excitons liés à l'Al et celle des paires donneurs accepteurs Al-N et Ga-N. Enfin l'apparition d'un nouveau défaut de structure appelée le « fourfold twin » a été observée. / The main topic of this thesis is the structural and optical characterization of SiC samples. The samples were divided in three groups: bulk, thick and thin epilayers. The bulk samples were grown with the CF-PVT technique and used a modified crystal holder geometry. The objective was to filter the defects to and create high purity and quality seeds of 3C-SiC. The thick epilayers were grown with the sublimation epitaxy technique, trying to demonstrate the creation of low impurity n and p type layers for device applications. Finally the thin epilayers were grown with the vapour-liquid-solid technique and doped with Ga impurities in an effort to create either heavily p-type doped samples and components for white LED applications. The samples were studied with low temperature photoluminescence, micro-Raman, SIMS and transmission electron microscopy. With the help of these techniques it was possible to determine the impurity concentration and identif y the n or p character of these samples. A qualitative analysis of the quality of the samples was done using both the observation of the structural defects and the information from the optical characterization techniques. We were able to acquire information about physical parameters of 3C-SiC like the binding energy of Ga and Al, the Al bound exciton fine structure and the Al-N and Ga-N donor acceptor pair fine structure. The appearance of a new structural defect called the fourfold twin was observed and presented. Carbure Silicium Photoluminescence à basse Temperature Micro-Raman Polytype Cubic Silicon Carbide Low Temepreature Photoluminescence Micro-Raman Transmission Electron Microscopy Polytype cubic
310	Porous polymeric materials for chromatography : Synthesis, functionalization and characterization Byström, Emil January 2009 (has links) Background: Separation science is heavily reliant on materials to fulfill ever more complicated demands raised by other areas of science, notably the rapidly expanding molecular biosciences and environmental monitoring. The key to successful separations lies in a combination of physical properties and surface chemistry of stationary phases used in liquid chromatographic separation, and this thesis address both aspects of novel separation materials. Methods: The thesis accounts for several approaches taken during the course of my graduate studies, and the main approaches have been i) to test a wild-grown variety of published methods for surface treatment of fused silica capillaries, to ascertain firm attachment of polymeric monoliths to the wall of microcolumns prepared in silica conduits; ii) developing a novel porogen scheme for organic monoliths including polymeric porogens and macromonomers; iii) evaluating a mesoporous styrenic monolith for characterization of telomers intended for use in surface modification schemes and; iv) to critically assess the validity of a common shortcut used for estimating the porosity of monoliths prepared in microconduits; and finally v) employing plasma chemistry for activating and subsequently modifying the surface of rigid, monodisperse particles prepared from divinylbenzene. Results: The efforts accounted for above have resulted in i) better knowledge of the etching and functionalization parameters that determine attachment of organic monoliths prepared by radical polymerization to the surface of silica; ii) polar methacrylic monoliths with a designed macroporosity that approaches the desired "connected rod" macropore morphology; iii) estab¬lishing the usefulness of monoliths prepared via nitroxide mediated polymerization in gradient polymer elution chromatography; iv) proving that scanning electron microscopy images are of limited value for assessing the macroporous properties of organic monoliths, and that pore measurements on externally polymerized monolith cocktails do not represent the porous properties of the same cocktail polymerized in narrow confinements; and v) showing that plasma bromination can be used as an activation step for rigid divinylbenzene particles to act as grafting handles for epoxy-containing telomers, that can be attached in a sufficiently dense layer and converted into carboxylate cation exchange layer that allows protein separations in fully aqueous eluents. porous polymer monolith pore size distribution nitrogen sorptiometry mercury intrusion porosimetry plasma functionalization Analytical Chemistry Analytisk kemi Analytical Chemistry Analytisk kemi Polymer Chemistry Polymerkemi

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