Global ETD Search

81	Etude des nouveaux modificateurs de frottement à base de molybdène pour la lubrification moteur Gorbatchev, Olga 24 July 2014 (has links) La zone Segment-Piston-Chemise (SPC) d’un moteur thermique est une source importante de dissipation d’énergie liée au frottement sévère. Il est important d’optimiser les lubrifiants agissant dans cette zone car ils ont un impact essentiel sur la durée de vie des pièces mécaniques et la réduction de la consommation énergétique des véhicules. Le dépôt de revêtements sur certaines pièces soumises à des frottements sévères est également une alternative intéressante, en particulier les revêtements carbonés de type DLC et diamant nanocristallin (NCD). La formulation des nouveaux lubrifiants moteurs doit tenir compte de la présence éventuelle de ces nouveaux matériaux. Dans ce travail de doctorat, l’action tribochimique de nouveaux additifs à base de molybdène, couplés à un additif anti-usure de type ZnDTP et à d’autres additifs de type modificateur de frottement, a été étudiée. Ces derniers sont depuis longtemps connus pour leur grande capacité à réduire le frottement grâce à la formation du composé lamellaire di-sulfure de molybdène (MoS2), notamment les additifs MoDTC dimer. Cependant la quantité importante de soufre qu’ils contiennent reste problématique du fait de son impact néfaste sur l’environnement. L’effet synergique d’un additif au molybdène purement organique, appelé Mo-organique, en combinaison avec un additif ZnDTP et d’une triamine grasse, a été découvert. Ce nouveau mélange ternaire permet de réduire jusqu’à 20% la contenance en soufre d’une formulation lubrifiante globale tout en améliorant les performances tribologiques par rapport à celles du MoDTC classique. De ce fait, une réduction du coefficient de frottement atteignant 50% a été observée. Une caractérisation physico-chimique multi-échelles des tribofilms binaires et ternaires dérivés du Mo-organique a été réalisée en utilisant une approche multi-techniques (XPS, ToF-SIMS, FIB/HRTEM). Un mécanisme réactionnel hypothétique conduisant à la formation du MoS2, passant par un composé intermédiaire de type « thiomolybdate » a été proposé. / The friction in the Piston-ring area is a significant cause of the energy waste. It is important to optimize the lubricants acting in this zone because they have an essential impact on the service life of the mechanical parts and the reduction of the energy consumption of vehicles. The coating on relevant part is also an interesting alternative, such as the carbon coating of the DLC type or a nano-crystalline diamond (NCD) coating. If such coating materials are used, the composition of new lubricants has to be adapted correspondingly. This doctoral work-studies the tribo-chemical action of new additives with molybdenum, coupled with an anti-wear additive of the ZnDTP type as well as with some other friction-modifying additives. Some of these additives, especially the MoDTC dimer, are known to reduce the friction through formation of the lamellar di-sulfur composite of molybdenum (MoS2). However, due to high sulfur content these additives produce significant adverse environmental effects. A synergy effect has been proven of a purely organic molybdenum additive, called Moorganic, combined with a ZnDTP additive and from a fatty triamine. This new ternary mixture allows reducing up to 20% the sulfur content in the lubricant’s global formula and improves the tribological properties in comparison with the classical MoDTC. Consequently, the observed reduction of friction coefficient reached 50%. Using the multi-technic approach (XPS, ToF-SIMS, FIB/HRTEM) we realized a multi-scale physicochemical characterization of the binary and ternary tribo-layers that derived from the Mo-organic. A reactional mechanism that leads to the MoS2 formation has been proposed; it goes through the intermediate composite of the « thiomolybdate » type. Frottement Usure Film tribochimique Molybdène organique Dithiophosphate de zinc Film de transfert Analyse de surface XPS SIMS FIB/TEM Friction Wear Tribochemical film Organic molybdenum Zinc dithiophosphate Transfer film Surface analysis XPS SIMS FIB/TEM
82	Využití vnitřní kompozitní výztuže při návrhu odolných betonových konstrukcí / The use of internal composite reinforcement in the design of durable concrete structures Koriťáková, Martina January 2022 (has links) The diploma thesis deals with processing of determining the shear strength of concrete structures reinforced with composite reinforcement, subjected to shear force, according to five different design approaches. The theoretical part of the thesis is closely related to the project FW01010520 - "Development of bent composite reinforcement for environmentally exposed concrete constructions", which is realized at the Institut of Concrete and Masonry Structures, Faculty of Civil Engineering, Brno University of Technology. The project deals with the shear strength of concrete beams reinforced with steel and composite reinforcement in various combinations. Then the load-bearing results gained within the project are compared with the values obtained by calculations according to the solved design approaches and computer software Atena Science. The second part of the diploma thesis deals with the static design and assessment of the cell structure. The cell is designed as a room inside of the medical building, where is placed device of magnetic resonance which is the reason why the cell is reinforced with non-magnetic composite reinforcement.
83	The Formation of Amorphous and Crystalline Damage in Metallic and Semiconducting Materials under Gallium Ion Irradiation Presley, Michael 28 December 2016 (has links) No description available. Materials Science Metallurgy Radiation Focused ion beam radiation damage FIB damage collision cascade sample preparation TEM STEM FIB crystalline defects amorphous amorphous damage needle damage measurement semiconductor metal intermetallic
84	The microstructure of thin film cadmium telluride photovoltaic materials Abbas, Ali January 2014 (has links) In this work cadmium telluride thin film photovoltaic devices have successfully been produced using a novel closed-field magnetron sputtering technique. This technique offers the possibility of producing cells in an all-in-one vacuum process with the potential to provide a new lower cost production route. The sputtered cadmium telluride layers were characterised in detail using a range of advanced microscopy based techniques both in the as deposited and after the cadmium chloride treated state, a treatment that is necessary to produce a working cell. In the as deposited condition the cadmium telluride layer was seen to have a fine-grained columnar structure containing a high density of stacking faults. After the cadmium chloride treatment these grains recrystallized and the new grains were equiaxed with a much lower density of intragranular defects. Similar effects were also observed in samples prepared using close space sublimation. To understand this recrystallization behaviour during the cadmium chloride treatment, the key treatment parameters were systematically varied. Chemical analysis in Scanning Transmission Electron Microscopy (STEM) showed that chlorine travelled down the cadmium telluride grain boundaries and accumulated adjacent to the cadmium telluride/cadmium sulphide interface. This interface is where the cadmium telluride grains were found to recrystallise first during interrupted cadmium chloride treatments. The nature of the stacking faults was examined using High Resolution Transmission Electron Microscopy (HR-TEM). This showed that in localised regions up to one plane of atoms per sequence was missing based on the expected zinc blende structure. This changed the packing of the atoms such that a local change in crystal structure occurred. This local change in phase was successfully mapped using Electron Backscatter Diffraction in planar section produced using Focused Ion Beam milling. This was subsequently studied in more detail using Transmission Electron Backscatter Diffraction in the Scanning Electron Microscope, where the intra-granular arrangement of the phases was observed. HR-TEM was used to quantitatively measure the linear defects in the cadmium telluride layer after thermal annealing with and without the cadmium chloride present. This showed that annealing alone resulted in only a modest reduction in the density of linear defects and grain recrysallisation only occurred in the presence of cadmium chloride. Cadmium magnesium telluride (CMT) was successfully grown epitaxially onto the cadmium telluride as an electron reflector layer to improve cell performance. During deposition the cell experienced high temperatures and this caused the stacking faults to return in a cell that had been previously cadmium chloride treated. This resulted in a reduction in cell efficiency, providing another link between linear defects and a degradation in cell performance. 621.31
85	3D imaging and modeling of carbonate core at multiple scales Ghous, Abid, Petroleum Engineering, Faculty of Engineering, UNSW January 2010 (has links) The understanding of multiphase flow properties is essential for the exploitation of hydrocarbon reserves in a reservoir; these properties in turn are dependent on the geometric properties and connectivity of the pore space. The determination of the pore size distribution in carbonate reservoirs remains challenging; carbonates exhibit complex pore structures comprising length scales from nanometers to several centimeters. A major challenge to the accurate evaluation of these reservoirs is accounting for pore scale heterogeneity on multiple scales. This is the topic of this thesis. Conventionally, this micron scale information is achieved either by building stochastic models using 2D images or by combining log and laboratory data to classify pore types and their behaviour. None of these capture the true 3D connectivity vital for flow characterisation. We present here an approach to build realistic 3D network models across a range of scales to improve property estimation through employment of X-ray micro-Computed Tomography (μCT) and Focussed Ion Beam Tomography (FIBT). The submicron, or microporous, regions are delineated through a differential imaging technique undertaken on x-ray CT providing a qualitative description of microporosity. Various 3-Phase segmentation methods are then applied for quantitative characterisation of those regions utilising the attenuation coefficient values from the 3D tomographic images. X-ray micro-CT is resolution limited and can not resolve the detailed geometrical features of the submicron pores. FIB tomography is used to image the 3D pore structure of submicron pores down to a scale of tens of nanometers. We describe the experimental development and subsequent image processing including issues and difficulties resolved at various stages. The developed methodology is implemented on cores from producing wackstone and grainstone reservoirs. Pore network models are generated to characterise the 3D interconnectivity of pores. We perform the simulations of petrophysical properties (permeability and formation resistivity) directly on the submicron scale image data. Simulated drainage capillary pressure curves are matched with the experimental data. We also present some preliminary results for the integration of multiscale pore information to build dual-scale network models. The integration of multiscale data allows one to select appropriate effective medium theories to incorporate sub-micron structure into property calculations at macro scale giving a more realistic estimation of properties. Focussed Ion Beam Tomography (FIB) Pore Network Model X-ray micro Computed Tomography (CT) Petrophysical Properties Microporosity Carbonate Reservoirs
86	Etudes expérimentale et numérique du comportement mécanique d'un composite métal – céramique : MoTiC30% Cédat, Denis 17 November 2008 (has links) (PDF) Dans le cadre du développement des réacteurs de génération IV, de nouvelles études sont menées dans le domaine des matériaux. L'objectif de ce travail est d'améliorer la compréhension du comportement mécanique et de l'endommagement de composites à matrice métallique Mo(TiC)x% contenant une forte fraction volumique de particules, et cela, dans le domaine de températures [25 – 700 °C].<br /><br />La caractérisation microstructurale a permis de comprendre l'histoire du matériau et d'identifier la nature d'une troisième phase (Mo,Ti)C fomée par diffusion du molybdène dans le carbure de titane. L'étude expérimentale a aussi révélé la percolation des particules céramiques au sein de la structure.<br />Les essais mécaniques ont mis en évidence les principales caractéristiques du matériau : le comportement macroscopique dépend à la fois de la vitesse de déformation et de la température. Ces mécanismes sont attribués au comportement thermiquement activé du molybdène.<br /><br />Nous proposons alors diverses simulations de microstructures comprenant des inclusions élastiques-fragiles dans une matrice viscoélastique. L'évolution du comportement mécanique du composite a été modélisée à l'aide d'une approche cristalline sur un agrégat 3D réel. L'agrégat numérique utilisé pour modéliser le comportement mécanique fait appel à une technique de reconstruction 3D via une acquisition par FIB/SEM/EBSD.<br /><br />Ainsi, la réponse du modèle est en bon accord avec les résultats expérimentaux et permet de décrire en fonction de la température :<br />- les mécanismes de plasticité du molybdène, en tenant compte de la transition basse/haute température ;<br />- l'endommagement du carbure de titane et les effets de la percolation. [SPI] Engineering Sciences Composite Céramique-métal Carbure de titane Plasticité cristalline Endommagement FIB/SEM/EBSD
87	CARACTÉRISATION PAR HOLOGRAPHIE ÉLECTRONIQUE ET SIMULATION DU DOPAGE 2D SUR SUBSTRAT SOI ULTRA-MINCE Cyril, Ailliot 04 November 2010 (has links) (PDF) L'holographie électronique "off-axis" est une technique de MET sensible à la densité locale de porteurs, elle permet facilement une cartographie 2D du potentiel électrostatique et, par son large champ de vue, une analyse des profils de dopants actifs, directement utilisables pour le calibrage des outils de simulation des procédés. Les travaux de cette thèse (convention CIFRE entre le CEA-LETI et STMicroelectronics) ont pour objet, d'une part l'établissement de protocoles de préparation des échantillons, d'acquisition des données en holographie électronique, et d'autre part la comparaison entre les résultats de la mesure et ceux de la simulation à l'aide des outils TCAD. Pour mener cette étude, nous avons, dans un premier temps, étudié l'influence des paramètres du MET sur la résolution spatiale et le niveau de bruit de l'holographie. Puis, sur des échantillons élémentaires, nous avons prouvé la présence d'une couche inactive et mis en évidence les effets de charges induits par le faisceau de mesure. Ces artefacts ont été observés aussi bien dans les échantillons préparés par polissage mécano-chimique que lors de l'usinage des échantillons par FIB. Notre étude montre d'une part que la couche inactive cristalline induite par les défauts ponctuels générés par cette technique est contrôlée par l'énergie du faisceau FIB, et d'autre part, que les charges électriques de l'échantillon créent une sous-estimation du potentiel mesuré, inversement proportionnelle à la concentration de dopants. Enfin, la maitrise des artefacts de la technique nous ont permis de caractériser des transistors nMOS sur film mince de silicium, avec comme objectif le calibrage de l'implantation et la diffusion de l'arsenic. Les limitations d'une utilisation pratique de l'holographie électronique ont été étudiées par la comparaison de cartographies de potentiel électrostatique mesurées par cette technique et simulées par TCAD. Holographie électronique Dopants Diffusion Caractérisation physico-chimique MET SOI FIB preparation
88	Fabrication and Applications of a Focused Ion Beam Based Nanocontact Platform for Electrical Characterization of Molecules and Particles Blom, Tobias January 2010 (has links) The development of new materials with novel properties plays an important role in improving our lives and welfare. Research in Nanotechnology can provide e.g. cheaper and smarter materials in applications such as energy storage and sensors. In order for this development to proceed, we need to be able to characterize the material properties at the nano-, and even the atomic scale. The ultimate goal is to be able to tailor them according to our needs. One of the great challenges concerning the characterization of nano-sized objects is how to achieve the physical contact to them. This thesis is focused on the contacting of nanoobjects with the aim of electrically characterizing them and subsequently understanding their electrical properties. The analyzed nanoobjects are carbon nanosheets, nanotetrapods, nanoparticles and molecular systems. Two contacting strategies were employed in this thesis. The first strategy involved the development of a focused ion beam (FIB) based nanocontact platform. The platform consists of gold nanoelectrodes, having nanogaps of 10-30 nm, on top of an insulating substrate. Gold nanoparticles, double-stranded DNA and cadmium telluride nanotetrapods have been trapped in the gaps by using dielectrophoresis. In certain studies, the gold electrodes have also been coated with conducting or non-conducting molecules, prior to the trapping of gold nanoparticles, in order to form molecular junctions. These junctions were subsequently electrically characterized to evaluate the conduction properties of these molecular systems. For the purpose of better controlling the attachment of molecules to the nanoelectrodes, a novel route to synthesize alkanedithiol coated gold nanoparticles was developed. The second contacting strategy was based on the versatility of the FIB instrument as a platform for in-situ manipulation and electrical characterization of non-functionalized and functionalized carbon nanosheets, where it was found that the functionalized samples had an increased conductivity by more than one order of magnitude. Both contacting strategies proved to be valuable for building knowledge around contacting and electrical characterization of nanoobjects Focused Ion Beam FIB Scanning Electron Microscopy SEM Nanogap electrodes Nanostructuring Nanofabrication Electron Beam Lithography Electrical characterization Dielectrophoresis
89	Microscopic Characterisation of Solar Cells : An Electron Microscopy Study of Cu(In,Ga)Se2 and Cu2ZnSn(S,Se)4 Solar Cells Wätjen, Jörn Timo January 2013 (has links) The sun provides us with a surplus of energy convertible to electricity using solar cells. This thesis focuses on solar cells based on chalcopyrite (CIGSe) as well as kesterite (CZTS(e)) absorber layers. These materials yield record efficiencies of 20.4 % and 11.1 %, respectively. Especially for CZTS(e), the absorber layers often do not consist of one single desired phase but can exhibit areas with deviating material properties, referred to as secondary phases. Furthermore, several material layers are required for a working solar cell, each exhibiting interfaces. Even though secondary phases and interfaces represent a very small fraction of the solar cell they can have a profound influence on the over-all electrical solar cell characteristics. As such, it is crucial to understand how secondary phases and interfaces influence the local electrical characteristics. Characterising secondary phases and interfaces is challenging due to their small sample volume and relatively small differences in composition amongst others. This is where electronmicroscopy, especially transmission electron microscopy, offers valuable insight to material properties on the microscopic scale. The main challenge is, however, to link these material properties to the corresponding electrical characteristics of a solar cell. This thesis uses electron beam induced current imaging and introduces a new method for JV characterisation of solar cells on the micron scale. Combining microscopic structural and electrical characterisation techniques allowed identifying and characterising local defects found in the absorber layer of CIGS solar cells after thermal treatment. Furthermore, CZTSe solar cells in this thesis exhibited a low photo-current density which is traced to the formation of a current blocking ZnSe secondary phase at the front contact interface. The electron microscopy work has contributed to an understanding of the chemical stability of CZTS and has shown the need for an optimised back contact interface in order to avoid chemical decomposition reactions and formation of detrimental secondary phases. With this additional knowledge, a comprehensive picture of the material properties from the macroscopic down to the microscopic level can be attained throughout all required material layers. TEM SEM FIB solar cell CIGS CZTS Alternative buffer layers Gallium gradients microscopic electrical characterisation Secondary Phases
90	Quantitative Messung von Dotiergebieten in FIB-präparierten Silizium-Halbleiterbauelementen mittels Elektronenholographie Lenk, Andreas 21 November 2008 (has links) (PDF) Das Einbringen von Dotierstoffen in das Substratmaterial ist einer der wichtigsten Teilprozesse in der Halbleiterindustrie. Größe, Lage und Konzentration elektrisch aktiver Dotiergebiete bestimmen wesentlich die Eigenschaften der mikroelektronischen Basisbauelemente und damit die Funktionalität der Endprodukte. Die kontinuierliche Verkleinerung dieser Bauelemente zieht steigende Anforderungen an die Präzision bei ihrer Herstellung nach sich. Analyseverfahren, mit denen die genannten Kenngrößen gemessen werden können, sind aus diesem Grund von hoher Bedeutung. Elektronenholographie ist eine dafür prinzipiell geeignete Messmethode, da sie eine zweidimensionale Vermessung der durch die Dotanden veränderten Potentialstruktur des Halbleiters in der geforderten Ortsauflösung von wenigen nm erlaubt. Ein Teil dieser Arbeit befasst sich mit der Optimierung der für die holographische Untersuchung wichtigen Parameter. Zu diesem Zweck werden sowohl präparative Aspekte wie geeignete Probendicke und Struktur der Proben als auch messtechnische Aspekte wie kohärente Beleuchtung und TEM-Parameter diskutiert. Während sich der Hauptteil der Arbeit mit den dabei gewonnenen wissenschaftlichen Erkenntnissen befasst, werden im Anhang die bei Präparation und Messung wichtigen Details ausführlich beschrieben. Ein wesentliches Problem bei der elektronenholographischen Messung stellt die Präparation der Objekte für die Untersuchung im TEM dar. Die einzige sinnvolle Möglichkeit für eine industrielle Anwendung ist die Zielpräparation mit dem fokussierten Ionenstrahl („FIB“), da keine andere Methode vergleichbar effizient arbeitet. Leider wird bei dieser Art von Präparation die Probe von der Oberfläche bis in eine gewisse Tiefe sowohl strukturell als auch elektrisch verändert. Diese Artefakte beeinflussen das Ergebnis der hochsensiblen holographischen Messung. Um die gewonnenen Daten dennoch verlässlich quantitativ auswerten zu können, muss klar zwischen ursprünglichen Objekteigenschaften und präparativ induzierten Schädigungen unterschieden werden. Um dieses Ziel zu erreichen, wurden durch die FIB-Präparation hervorgerufene Schädigungen der Probe systematisch analysiert. Mit Hilfe von SIMS konnte die Tiefenverteilung des beim Ionenschneiden eingedrungenen Fremdmaterials gemessen werden. Es wurden Querschnitte von FIB-Proben durch konventionelle, holographische sowie holographisch-tomographische Abbildung im TEM an einer eigens dafür entwickelten nadelförmigen Probengeometrie untersucht. Dabei wurden die entstandenen strukturellen und elektrischen Veränderungen beobachtet und quantitativ charakterisiert. Der Einsatz von Tomographie erlaubte schließlich die Messung der Potentialverteilung im Inneren der Nadeln ohne eine Verfälschung durch Projektionseffekte. Es wurde gezeigt, dass die über die Schädigungen gewonnenen Erkenntnisse für eine Korrektur der holographischen Daten genutzt werden können. Dazu wurden entsprechende Untersuchungen an verschiedenen Bauelementen aus der Halbleiterindustrie durchgeführt. Die korrigierten Ergebnisse wurden dabei stets mit den theoretischen Erwartungen verglichen. Elektronenholographie Halbleiter Dotiergebiete FIB-Präparation Elektronentomographie Electron Holography Semiconductor Doped Areas FIB.Preparation Electron Tomography ddc:530 rvk:UP 2800

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