Global ETD Search

111	A comparison of SPS and HP sintered, electroless copper plated carbon nanofibre composites for heat sink applications Ullbrand, Jennifer January 2009 (has links) <p>The aim of this study is to synthesize a material with high thermal conductivity and a low coefficient of thermal expansion (CTE), useful as a heat sink. Carbon nanofibres (CNF) are first coated with copper by an electroless plating technique and then sintered to a solid sample by either spark plasma sintering (SPS) or hot pressing (HP). The final product is a carbon nanofibre reinforced copper composite. Two different fibre structures are considered: platlet (PL) and herringbone (HB). The influence of the amount of CNF reinforcement (6-24 %wt), on the thermal conductivity and CTE is studied. CNF has an excellent thermal conductivity in the direction along the fibre while it is poor in the transverse direction. The CTE is close to zero in the temperature range of interest. The adhesion of Cu to the CNF surface is in general poor and thus improving the the wetting of the copper by surface modifications of the fibres are of interest such that thermal gaps in the microstructure can be avoided. The poor wetting results in CNF agglomerates, resulting in an inhomogeneous microstructure. In this report a combination of three different types of surface modifications has been tested: (1) electroless deposition of copper was used to improve Cu impregnation of CNF; (2) heat treatment of CNF to improve wetting; and (3) introduction of a Cr buffer layer to further enhance wetting. The obtained composite microstructures are characterized in terms of chemical composition, grain size and degree of agglomeration. In addition their densities are also reported. The thermal properties were evaluated in terms of thermal diffusivity, thermal conductivity and CTE. Cr/Cu coated platelet fibres (6wt% of CNF reinforcement) sintered by SPS is the sample with the highest thermal conductivity, ~200 W/Km. The thermal conductivity is found to decrease with increasing content of CNFs.</p> electroless plating SPS spark plasma sintering HP hot pressing CNF carbon nanofibre carbon nanofiber heat sinks thermal conductivity thermal diffusivity Cu composite flash technique Physics Fysik
112	Properties of biologically relevant nanocomposites: effects of calcium phosphate nanoparticle attributes and biodegradable polymer morphology Kaur, Jasmeet 05 April 2010 (has links) This research is directed toward understanding the effect of nanoparticle attributes and polymer morphology on the properties of the nanocomposites with analogous nanoparticle chemistry. In order to develop this understanding, polymer nanocomposites containing calcium phosphate nanoparticles of different specific surface areas and shapes were fabricated and characterized through thermal and thermomechanical techniques. Nanoparticles were synthesized using reverse microemulsion technique. For nanocomposites with different surface area particles, the mobility of amorphous polymer chains was restricted significantly by the presence of particles with an interphase network morphology at higher loadings. Composites fabricated with different crystallinity matrices showed that the dispersion characteristics and reinforcement behavior of nanoparticles were governed by the amount of amorphous polymer fraction available. The study conducted on the effect of nanoparticle shape with near-spherical and nanofiber nanoparticles illustrated that the crystallization kinetics and the final microstructure of the composites was a function of shape of the nanoparticles. The results of this research indicate that nanoparticle geometry and matrix morphology are important parameters to be considered in designing and characterizing the structure-property relationship in polymer nanocomposites. Matrix morphology Nanoparticle attributes Matrix crystallinity Surface area Nanofiber Biodegradable Polyhydroxybutyrate Polycaprolactone Nanocomposites Calcium phosphate Nanoparticles Hydroxyapatite Nanocomposites (Materials) Calcium phosphate Polymers Morphology Biodegradation
113	A comparison of SPS and HP sintered, electroless copper plated carbon nanofibre composites for heat sink applications Ullbrand, Jennifer January 2009 (has links) The aim of this study is to synthesize a material with high thermal conductivity and a low coefficient of thermal expansion (CTE), useful as a heat sink. Carbon nanofibres (CNF) are first coated with copper by an electroless plating technique and then sintered to a solid sample by either spark plasma sintering (SPS) or hot pressing (HP). The final product is a carbon nanofibre reinforced copper composite. Two different fibre structures are considered: platlet (PL) and herringbone (HB). The influence of the amount of CNF reinforcement (6-24 %wt), on the thermal conductivity and CTE is studied. CNF has an excellent thermal conductivity in the direction along the fibre while it is poor in the transverse direction. The CTE is close to zero in the temperature range of interest. The adhesion of Cu to the CNF surface is in general poor and thus improving the the wetting of the copper by surface modifications of the fibres are of interest such that thermal gaps in the microstructure can be avoided. The poor wetting results in CNF agglomerates, resulting in an inhomogeneous microstructure. In this report a combination of three different types of surface modifications has been tested: (1) electroless deposition of copper was used to improve Cu impregnation of CNF; (2) heat treatment of CNF to improve wetting; and (3) introduction of a Cr buffer layer to further enhance wetting. The obtained composite microstructures are characterized in terms of chemical composition, grain size and degree of agglomeration. In addition their densities are also reported. The thermal properties were evaluated in terms of thermal diffusivity, thermal conductivity and CTE. Cr/Cu coated platelet fibres (6wt% of CNF reinforcement) sintered by SPS is the sample with the highest thermal conductivity, ~200 W/Km. The thermal conductivity is found to decrease with increasing content of CNFs. electroless plating SPS spark plasma sintering HP hot pressing CNF carbon nanofibre carbon nanofiber heat sinks thermal conductivity thermal diffusivity Cu composite flash technique Physics Fysik
114	Plazmová modifikace práškových materiálů / Plasma modification of powder materials ČERNÝ, Pavel January 2011 (has links) Thesis is focused on plasma modification of materials. The work has the character of a search of available literature, especially the papers presented in impacted journals. The aim is to provide a broader overview of the subject. The first section describes the most commonly modified powdered materials. The second part is focused on the plasma modification, the reasons for its use, capabilities and benefits respectively and disadvantages of these processes. The following sections are devoted to plasma discharges, plasma reactors, aspects of plasma modification and companies engaged in production, or modification of powders. Each chapter is intended to provide an overview of the modified powder materials, processes within the plasma discharges, construction and use of plasma reactors, plasma modification of aspects and the market situation in the context of powdered materials and companies dealing with the plasma modification.
115	Hybrid core-shell nanowire electrodes utilizing vertically aligned carbon nanofiber arrays for high-performance energy storage Klankowski, Steven Arnold January 1900 (has links) Doctor of Philosophy / Department of Chemistry / Jun Li / Nanostructured electrode materials for electrochemical energy storage systems have been shown to improve both rate performance and capacity retention, while allowing considerably longer cycling lifetime. The nano-architectures provide enhanced kinetics by means of larger surface area, higher porosity, better material interconnectivity, shorter diffusion lengths, and overall mechanical stability. Meanwhile, active materials that once were excluded from use due to bulk property issues are now being examined in new nanoarchitecture. Silicon was such a material, desired for its large lithium-ion storage capacity of 4,200 mAh g[superscript]-1 and low redox potential of 0.4 V vs. Li/Li[superscript]+; however, a ~300% volume expansion and increased resistivity upon lithiation limited its broader applications. In the first study, the silicon-coated vertically aligned carbon nanofiber (VACNF) array presents a unique core-shell nanowire (NW) architecture that demonstrates both good capacity and high rate performance. In follow-up, the Si-VACNFs NW electrode demonstrates enhanced power rate capabilities as it shows excellent storage capacity at high rates, attributed to the unique nanoneedle structure that high vacuum sputtering produces on the three-dimensional array. Following silicon’s success, titanium dioxide has been explored as an alternative highrate electrode material by utilizing the dual storage mechanisms of Li+ insertion and pseudocapacitance. The TiO[subscript]2-coated VACNFs shows improved electrochemical activity that delivers near theoretical capacity at larger currents due to shorter Li[superscript]+ diffusion lengths and highly effective electron transport. A unique cell is formed with the Si-coated and TiO[subscript]2-coated electrodes place counter to one another, creating the hybrid of lithium ion battery-pseudocapacitor that demonstrated both high power and high energy densities. The hybrid cell operates like a battery at lower current rates, achieving larger discharge capacity, while retaining one-third of that capacity as the current is raised by 100-fold. This showcases the VACNF arrays as a solid platform capable of assisting lithium active compounds to achieve high capacity at very high rates, comparable to modern supercapacitors. Lastly, manganese oxide is explored to demonstrate the high power rate performance that the VACNF array can provide by creating a supercapacitor that is highly effective in cycling at various high current rates, maintaining high-capacity and good cycling performance for thousands of cycles. Vertically aligned carbon nanofiber Silicon Manganese oxide Lithium-ion batteries Titanium oxide Energy storage Chemistry (0485) Energy (0791) Materials Science (0794)
116	Synthèse et caractérisation de nouvelles nanostructures à base d’oxyde et de carbure de Fe / Synthesis and characterization of new nanostructures based on oxide and iron carbide Eid, Cynthia Joseph 30 September 2010 (has links) Comme les propriétés physiques d'un matériau à l’échelle nanométrique sont largement dépendantes de la taille et de la forme des nanostructures, il est inutile de synthétiser de nouvelles compositions et morphologies. L’étude avancée de leur structure par les techniques de caractérisation usuelles (MET, MEB, DRX, Raman…) permettra de collecter toutes les informations nécessaires à la compréhension de leurs propriétés physiques (magnétiques, optiques, électriques). Dans ce manuscrit, nous décrirons plusieurs approches d’élaboration de nanostructures 0D, 1D et 2D multifonctionnelles afin de mieux connaître les paramètres qui contrôlent leur composition chimique et leur structure. De plus, ce travail de recherche a abouti à la synthèse de nouveaux matériaux à base d’oxyde et de carbure de fer. Des nanofibres magnétiques ayant des morphologies originales « Ruban » et « tube » ont été élaborées par la technique d’électrospinning en modifiant plusieurs paramètres expérimentaux : concentration de la solution, atmosphères de traitement thermique, température de recuit… De plus, des couches minces guidantes dopées par des nanostructures magnétiques ont été préparées par la technique dip-coating. Nous avons mené une étude complexe et détaillée sur les propriétés structurales de ces matériaux afin de définir les paramètres expérimentaux qui permettront d’obtenir des nano objets de bonne qualité. Dans un but ultime, nous souhaiterons explorer les possibilités d’application de ces matériaux qui présentent à la fois des caractéristiques électriques et magnétiques. / The physical properties of a nanomaterial strongly depend on the size and the shape of the nanostructure. As a consequence, it is interesting to elaborate new materials with different compositions and morphologies. The advanced study on the structure using common characterization techniques (TEM, MEB, XRD, Raman…) allows us to collect all the important information on their physical properties (magnetic, optical and electrical properties). In this thesis, we describe multiple ways to elaborate multifunctional nanostructures with 0D, 1D and 2D in order to study the parameters that control their chemical composition and structure. Besides, this research lead to the elaboration of new nanomaterials based on the oxide and the carbide forms of iron. Magnetic nanofibers with different morphologies (belts, tubes) were prepared using the electrospinning technique while controlling several experimental parameters : solution concentration, pyrolysis atmosphere, thermal treatment temperature… Moreover, thin layers doped with magnetic nanostructures were deposited on a pyrex substrate using the dip-coating technique. A full and detailed study on their structural properties was performed in order to reach the experimental parameters that allow us to obtain high quality products. Finally, we wish to explore the possible applications of these materials that present interesting electrical and magnetic characteristics. Nanotube Nanofibre Hématite Cémentite Électrospinning Dip-coating Oxyde de fer Carbure de fer Nanotube Nanofiber Hematite Cementite Electrospinning Dip-coating Iron oxide Iron carbide
117	Auto-assemblage de protéines pour la bioélectronique : étude du tranport de charges dans les fibres amyloïdes / Protein self-assembly for bioelectronics : study of charges transport in amyloid fibers Rongier, Anaëlle 13 February 2018 (has links) Les fibres amyloïdes sont des biomatériaux prometteurs pour la bioélectronique, en particulier pour l’interfaçage avec les systèmes biologiques. Ces fibres, formées par l’auto-assemblage de protéines, sont aisément synthétisables et modifiables/fonctionnalisables. Elles possèdent de surcroît des propriétés physiques remarquables notamment en termes de stabilité et de résistance mécanique. Nous avons étudié les mécanismes de conductions de charges dans les fibres formées par la protéine HET-s(218-289), seules fibres amyloïdes dont la structure atomique soit connue. Les échantillons ont été caractérisés électriquement et électrochimiquement sous la forme de films « secs ». L’influence de plusieurs paramètres sur la conductivité, entre autres la température, l’humidité ou encore la lumière, a été investiguée. Nous avons montré que l’organisation de la protéine en fibres permet la mise en place de processus de transport de charges intrinsèques. De plus, l’eau joue un rôle essentiel dans ces mécanismes et les principaux porteurs de charges sont certainement des protons. En parallèle, une simulation de dynamique moléculaire appuyée notamment par des expériences de diffusions des neutrons, a mis en évidence une forte interaction entre l’eau et les fibres. Deux canaux d’eau stabilisés par liaisons hydrogènes se formeraient le long des fibres. Ces derniers peuvent permettre le transport de protons par un mécanisme de type Grotthuss. Des réactions électrochimiques, en particulier l’électrolyse de l’eau, seraient la source des protons transportés grâce aux fibres. Cela conduit à l’instauration d’un courant catalytique à partir d’un seuil de tension de polarisation. Enfin, deux effets photo-électriques ont été observés lorsque les fibres sont irradiées entre 200 et 400 nm. Le premier est un photo-courant qui serait dû à la photolyse de l’eau adsorbée dans les échantillons. Le second, qualifié de « photo-courant inverse », se produit plus spécifiquement à la longueur d’onde de 280nm et seulement en présence de dioxygène. Il engendre une diminution de la conductivité. Cela serait dû à une réaction entre l’état triplet des tryptophanes des fibres et le dioxygène, captant in fine des protons. / Amyloid fibers are very promising biomaterials for bioelectronics, especially for interfacing with biological systems. These self-assembled proteins fibers are easy to synthetize, to tune and to functionalize. Their physical properties such as stability and mechanical strength are noticeable. We studied charge transport processes in HET-s(218-289), the only amyloid fibers we know the atomic structure. The samples were characterized as “dried” films by electrical measurement and electrochemistry. The influence of several parameters such as temperature, humidity or light was investigated. We demonstrated that the fiber organization allows intrinsic charge transport mechanisms in which water plays a crucial role. Furthermore, the dominant charge carriers would be protons. Molecular dynamic simulation and neutron diffusion experiments run in parallel show strong water-fibers interactions. In particular, H-bonded water wires can be formed along the fibers and support proton transport according to a Grotthuss-like mechanism. Proton production would result from electrochemical reactions, especially from water electrolysis. Therefore a catalytic current is detected when the bias exceeds a certain threshold. In addition, two photoelectric phenomena were observed when the fibers are irradiated with near UV light (200-400nm). The first one is a photocurrent probably due to water photo-splitting. The other occurs specifically at 280nm wavelength and in the presence of molecular oxygen. It leads to a decrease of the sample conductivity. This likely results from chemical reaction(s) between triplet-state tryptophan and oxygen that consumes protons. Bioélectronique Nanofibre Transport électronique Semi-Conducteur organique Systèmes modèles bioinspirés Bioelectronics Nanofiber Electronic transport Organic semiconductors Bioinspired model systems 530 570
118	Transplantace limbálních kmenových buněk a jejich využití k rekonstrukci povrchu oka / Limbal stem cell transplantation and their utilization for ocular surface reconstruction. Lenčová, Anna January 2015 (has links) Aims: Limbal stem cell (LSC) deficiency is one of the most challenging ocular surface diseases. The aim of this thesis was to study damaged ocular surface reconstruction. Therefore, a mouse model of limbal transplantation was estab- lished. Furthermore, LSC isolation, transfer of LSCs and bone marrow-derived mesenchymal stem cells (MSCs) on nanofiber scaffolds were studied. Material and methods: Syngeneic, allogeneic and xenogeneic (rat) limbal grafts were transplanted orthotopically into BALB/c mice. Graft survival, immune re- sponse and the effect of monoclonal antibodies (mAb) (anti-CD4 and anti-CD8 cells) were analyzed. Mouse LSCs were separated by Percoll gradient; subse- quently, they were analyzed for the presence of LSC and differentiation corneal epithelial cell markers and characteristics using real-time PCR and flow cytom- etry. Nanofiber scaffolds seeded with LSCs and MSCs were transferred onto the damaged ocular surface in mouse and rabbit models. Cell growth on scaffolds, post-operative inflammatory response and survival of transferred cell were ana- lyzed. Results: Limbal allografts were rejected promptly by the Th1-type of immune response (IL-2, IFN-γ) involving CD4+ cells and nitric oxide produced by macro- phages, contrary to the prevailing Th1 and Th2 immune responses (IL-4, IL-10) in...
119	Experimentální modely přenosu kmenových buněk pro léčebné účely / Experimental models of a transfer of stem cells for therapeutic purposes Faltýsková, Helena January 2010 (has links) Experimental models of a transfer of stem cells for therapeutic purposes Abstract Stem cell therapy currently represents a standard procedure of treating a wide variety of hereditary diseases and serious injuries. Development of the most suitable way of transfer of stem cells into the patient body remains very important question concerning this type of therapy. In our experiments we used nanofiber scaffolds for stem cell cultivation and their subsequent transfer. These nanofibers were prepared by the original needleless electrospun NanospiderTM technology. Allogeneic cornea or skin graft were transplanted from B6 mice to BALB/c mice. The grafts were covered by a nanofibrous scaffold with cultivated stem cells. Stem cells were stained by an imunofluorescent dye to enable us to monitore their migration from nanofibers into tissues and consequent distribution in the body and characterize changes of this distribution in the time. The methods of ELISA and PCR were used to confirm that mesenchymal stem cells support the production of antiinflammatory cytokines IL-4 and IL-10 and contribute to inhibition of production of proinflammatory cytokines IL-1, IFNγ and inducible nitric oxide synthase. We confirmed an important beneficial role of nanofiber scaffolds in transplantation of mesenchymal stem cells. Nanofiber...
120	Transplantace limbálních kmenových buněk a jejich využití k rekonstrukci povrchu oka / Limbal stem cell transplantation and their utilization for ocular surface reconstruction. Lenčová, Anna January 2015 (has links) Aims: Limbal stem cell (LSC) deficiency is one of the most challenging ocular surface diseases. The aim of this thesis was to study damaged ocular surface reconstruction. Therefore, a mouse model of limbal transplantation was estab- lished. Furthermore, LSC isolation, transfer of LSCs and bone marrow-derived mesenchymal stem cells (MSCs) on nanofiber scaffolds were studied. Material and methods: Syngeneic, allogeneic and xenogeneic (rat) limbal grafts were transplanted orthotopically into BALB/c mice. Graft survival, immune re- sponse and the effect of monoclonal antibodies (mAb) (anti-CD4 and anti-CD8 cells) were analyzed. Mouse LSCs were separated by Percoll gradient; subse- quently, they were analyzed for the presence of LSC and differentiation corneal epithelial cell markers and characteristics using real-time PCR and flow cytom- etry. Nanofiber scaffolds seeded with LSCs and MSCs were transferred onto the damaged ocular surface in mouse and rabbit models. Cell growth on scaffolds, post-operative inflammatory response and survival of transferred cell were ana- lyzed. Results: Limbal allografts were rejected promptly by the Th1-type of immune response (IL-2, IFN-γ) involving CD4+ cells and nitric oxide produced by macro- phages, contrary to the prevailing Th1 and Th2 immune responses (IL-4, IL-10) in...

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