Global ETD Search

671	Silver-containing diamond-like carbon deposited by plasma as versatile antibacterial coatings Cloutier, Maxime 24 April 2018 (has links) Les infections associées au milieu hospitalier demeurent une cause majeure de mortalité et de morbidité dans le monde, malgré plusieurs décennies dédiées à promouvoir une meilleure surveillance et des méthodes de désinfection plus complètes. La capacité des bactéries pathogènes à survivre sur des substrats solides a été identifiée comme un facteur clé de la pathogenèse de ces infections, en multipliant les sources de transmission et de contamination. Au niveau de la recherche, cette situation s’est récemment traduite par un intérêt marqué pour le développement de revêtements antibactériens novateurs pouvant constituer une ligne de défense complémentaire contre la colonisation bactérienne de surfaces, pourvu qu’ils puissent résister à l’environnement rigoureux des établissements de santé. Dans cette thèse, nous avons émis l'hypothèse qu'un revêtement antibactérien avec une stabilité supérieure pouvait être déposé en utilisant un procédé plasma modulable, de sorte que les propriétés du revêtement résultant pourraient être adaptées aux exigences de différentes situations ou applications. Par conséquent, des revêtements nanocomposites de carbone amorphe adamantin contenant de l'argent (Ag-DLC) ont été développés et étudiés comme plate-forme polyvalente pour des surfaces antibactériennes. L’intérêt de ce matériau réside dans la combinaison des excellentes propriétés mécaniques, de la résistance à l'usure et de l'inertie chimique du carbone amorphe adamantin avec les propriétés antibactériennes à large spectre des nanomatériaux d'argent au sein d’un même revêtement déposé par plasma. Ce travail a d'abord identifié les défis de conception spécifiquement associés au développement de revêtements antibactériens pour le milieu hospitalier. Des analyses approfondies des revêtements Ag-DLC ont ensuite démontré une bonne efficacité antibactérienne in vitro ainsi qu’une stabilité des propriétés, de la structure et de l’état chimique des revêtements dans le temps. L'étendue de la polyvalence des revêtements Ag-DLC a été évaluée au travers de l’identification des mécanismes de croissance principaux, permettant d’obtenir des informations essentielles sur la façon dont les propriétés des films, telles que la dureté, la teneur et la distribution d’argent, pouvaient être contrôlées en ajustant des paramètres spécifiques du dépôt plasma. De plus, un traitement de surface in situ a été développé pour surmonter les problèmes de délamination et a montré la capacité de favoriser l'adhérence de revêtements DLC sur des substrats métalliques. Dans l'ensemble, cette étude a mis en évidence l'importance de la stabilité dans l'application des revêtements antibactériens et a démontré le vaste potentiel des procédés plasma pour le dépôt de revêtements antibactériens stables avec des propriétés adaptables. / Healthcare-associated infections remain a major cause of mortality and morbidity worldwide, with a substantial financial burden on society, despite decades of monitoring and disinfection efforts. The ability of pathogenic bacteria to survive on solid substrates has emerged as a key contributing factor in the pathogenesis of these infections by multiplying the sources of transmission and contamination. This has prompted investigations into the development of innovative antibacterial coatings, which could provide a complementary barrier against bacterial colonization of surfaces provided that they can withstand the harsh operating environment of healthcare facilities. In this thesis, we hypothesized that an antibacterial coating with superior stability could be deposited using a tailorable plasma process, so that the resulting coatings’ properties could be adapted to match the requirements of different situations or applications. Therefore, silver-containing diamond-like carbon (Ag-DLC) nanocomposite coatings were developed and investigated as a versatile platform material for antibacterial surfaces. The interest of this material lies in the combination of the excellent mechanical properties, wear-resistance and chemical inertness of diamond-like carbon with the broad-spectrum antibacterial properties of silver nanomaterials in a single, plasma-deposited coating. This work first identified the specific design challenges associated with the development of antibacterial coatings for healthcare environments. Thorough investigations of Ag-DLC coatings then revealed good antibacterial efficacy in vitro as well as stability of the coatings’ properties, structure, and chemistry over time. The extent of the tailorability of Ag-DLC coatings was also assessed through the identification of the main growth mechanisms, providing insights on how the film’s properties, such as the hardness, silver content, and silver distribution, could be controlled by adjusting specific plasma deposition parameters. Furthermore, an in situ interface plasma treatment was developed to overcome delamination issues and showed the ability to promote the adhesion of high stress DLC coatings on metallic substrates. Overall, this study highlighted the importance of stability in the application of antibacterial coatings and demonstrated the vast potential of plasma processes for the deposition of stable antibacterial coatings with tunable properties. TN 7.5 UL 2017 Antibactériens Revêtement de surface Argent Carbone -- Composés Matériaux nanocomposites Dispositifs à plasma
672	Mise au point des revêtements nanocomposites multicouches transparents polymérisés sous ultraviolets pour le bois à usage intérieur Nguegang Nkeuwa, William 19 April 2018 (has links) Ce travail de recherche comprenait deux volets. Le premier volet avait comme objectif général d’améliorer les propriétés barrières et mécaniques de la couche de surface devant constituer le revêtement multicouche (MC) pour le bois. L’objectif général du second volet visait quant à lui à augmenter l’adhérence du système [MC/surface du bois]. Dans le premier volet, des revêtements polymérisés sous ultraviolets (UV) pour la couche de surface ont été préparés en utilisant trois grades de nanoargile commerciale dispersés (1 et 3 % en masse totale dans la formulation) dans un oligomère commercial du type époxy acrylate. La morphologie des revêtements nanocomposites a été étudiée par diffraction des rayons X et par microscopie électronique à transmission (MET). La propriété barrière, la clarté optique ainsi que les propriétés mécaniques de ces revêtements ont également été évalués. Dans le deuxième volet, les surfaces de bois du bouleau jaune (Betula alleghaniensis Britton) ont été protégées avec six types de MC. Les formulations polymérisables sous UV pour la couche d’imprégnation et la couche de surface contenaient respectivement la nanosilice (NS : 0 et 0,5 %) et la nanoargile (NA : 0, 1 et 3 %). La morphologie de la section transversale du système [MC/surface du bois] a été étudiée par microscopie électronique à balayage (MEB) et par MET. Enfin, l’adhérence du système [MC/surface du bois] a été investiguée en fonction de l’humidité relative (HR). Les images de MET révèlent que la C30B a été moins bien dispersée que la C10A et la C15A, lesquelles ont donné lieu à l’obtention des revêtements nanocomposites dont la morphologie serait du type intercalée. Les nanoargiles ont un effet autant sur la propriété barrière que sur la clarté optique. Parmi les trois grades de nanoargiles, la C10A serait idéale pour une application pratique (salles de bains) et a été utilisée comme agent de renfort pour la couche de surface des MC. La contrainte d’adhérence du système [MC/surface du bois] a été plus élevée pour les échantillons conditionnés à 80% d’HR que pour ceux conditionnés à 40% d’HR. Le revêtement multicouche 5 (0,5% NS – 1% NA) serait idéal comme système de protection. / This research consists in two sections. The main objective of the first section was to improve barrier and mechanical properties of topcoats for wood furniture; while for the second section, the main objective was to increase the adhesion of multilayer coatings on wood surfaces. In the first section, free standing UV-cured coatings were prepared by using three different types of commercial organoclays. These nanoparticles were dispersed (1 and 3 wt % into the formulation) into a commercial epoxy acrylate oligomer. The morphology of these nanocomposites was studied by X-ray diffraction and by transmission electron microscopy (TEM). The barrier property (WVTR: water vapor transmission rate), optical clarity and mechanical tests of these nanocomposites were also assessed. In the second section, surfaces of yellow birch wood (Betula alleghaniensis Britton) were protected with six different types of multilayer coatings (MCs). Prepared primer and topcoat UV-curable formulations constituting these MCs contained, respectively nanosilica (NS: 0 and 0.5 wt %) and nanoclay (NC: 0, 1 and 3 wt %). The morphology of the cross-section of coated wood samples was studied by means of both scanning and transmission electron microscopy (SEM and TEM analysis respectively). The adhesion strength of these MCs on wood surfaces was assessed as a function of relative humidity (RH). TEM images reveal that C30B was not found to be dispersible into the acrylate matrix; while both UV-cured nanocomposites containing C10A and C15A respectively seemed to have an intercalated morphology. All the organoclays used in this study have had an effect on both WVTR and optical clarity. Among the three different types of organoclays, C10A appears to be the ideal reinforcing agent for practical application (bathrooms) and was used for topcoat constituting MCs on wood surfaces. The adhesion strength of coated wood samples conditioned at 80% RH was higher than that obtained on those conditioned at 40% RH. Multilayer coating 5 (0.5% NS–1% NC) appears to be the ideal protection system. SD 121 UL 2013 Produits de préservation du bois Revêtement de surface Matériaux nanocomposites
673	Utilizing Embedded Sensing for the Development of Piezoresistive Elastodynamics Julio Andres Hernandez (14684092) 21 July 2023 (has links) <p>Obtaining full-field \emph{dynamic} material state awareness would have profound and wide-ranging implications across many fields and disciplines. For example, achieving dynamic state awareness in soft tissues could lead to the early detection of pathophysiological conditions. Applications in geology and seismology could enhance the accuracy of locating mineral and hydrocarbon resources for extraction or unstable subsurface formations. Ensuring safe interaction at the human-machine interfaces in soft robotic applications is another example. And as a final representative example, knowing real-time material dynamics in safety-critical structures and infrastructure can mitigate catastrophic failures. Because many materials (e.g., carbon fiber-reinforced polymers composites, ceramic matrix composites, biological tissues, cementitious and geological materials, and nanocomposites) exhibit coupling between their mechanical state and electrical transport characteristics, self-sensing via the piezoresistive effect is a potential gateway to these capabilities. While piezoresistivity has been mostly explored in static and quasi-static conditions, using piezoresistivity to achieve dynamic material state awareness is comparatively unstudied. Herein lies the significant gap in the state of the art: the piezoresistive effect has yet to be studied for in-situ dynamic sensing.</p> <p><br></p> <p>In this thesis, the gap in the state of the art is addressed by studying the piezoresistive effect of carbon nanocomposites subject to high-rate and transient elastic loading. Nanocomposites were chosen merely as a representative self-sensing material in this study because of their ease of manufacturability and our good understanding of their electro-mechanical coupling. Slender rods were manufactured using epoxy, modified with a small weight fraction of nanofillers such as carbon black (CB), carbon nanofibers (CNFs), and multi-walled carbon nanotubes (MWCNTs), and subject to loading states such as steady-state vibration at structural frequencies ($10^2-10^4$ Hz), controlled wave packet excitation, and high-strain rate impact loading in a split-Hopkinson pressure bar. This work discovers foundational principles for dynamic material state awareness through piezoresistivity. </p> <p><br></p> <p>Three major scholarly contributions are made in this dissertation. First, an investigation was pursued to establish dynamic, high-strain rate sensing. This investigation clearly demonstrated the ability of piezoresistivity to accurately track rapid and spatially-varying deformation for strain rates up to $10^2$ s$^{-1}$. Second, piezoresistivity was used to detect steady-state vibrations common at structural frequencies. Utilizing simple signal processing techniques, it was possible to extract the excitation frequency embedded into the collected electrical measurements. The third contribution examined the dynamic piezoresistive effect through an array of surface-mounted electrodes on CNF/epoxy rods subject to highly-controlled wave packet excitation. Electrode-spacing adjustments were found to induce artificial signal filtering by containing larger portions of the injected wave packets. The strain state in the rod was found after employing an inverse conductivity-to-mechanics model, thereby demonstrating the possibility of deducing actual in-situ strains via this technique. A digital twin in ABAQUS was constructed, and an elastodynamic simulation was conducted using identical dynamic loading, the results of which showed very good agreement with the piezo-inverted strains. </p> <p><br></p> <p>This work creates the first intellectual pathway to full-field dynamic embedded sensing. This work has far-reaching potential applications in many fields, as numerous materials exhibit self-sensing characteristics through deformation-dependent changes to electrical properties. Therefore, \emph{piezoresistive elastodynamics} has the incredible potential to be applied not just in structural applications but in other potentially innovated applications where measuring dynamic behavior through self-sensing materials is possible. </p> Aerospace structures Structural dynamics Composite and hybrid materials Nanomaterials nanocomposites composites piezoresistivity behavior dynamics vibration
674	Processing, Optimization And Characterization Of Fire Retardant Polymer Nanocomposites Zhuge, Jinfeng 01 January 2010 (has links) Fiber reinforced polymeric composites (FRPC) have superior physical and mechanical properties, such as high specific strength, light weight, and good fatigue and corrosion resistance. They have become competitive engineering materials to replace conventional metallic materials in many important sectors of industry such as aircraft, naval constructions, ships, buildings, transportation, electrical and electronics components, and offshore structures. However, since FRPC contain polymer matrix, the polymer composites and their structures are combustible. FRPC will degrade, decompose, and sometimes yield toxic gases at high temperature or subject to fire conditions. The objective of this study is to design and optimize fire retardant nanopaper by utilizing the synergistic effects of different nanoparticles. A paper-making technique that combined carbon nanofiber, nanoclay, polyhedral oligomeric silsesquioxanes, graphite nanoplatelet, and ammonium polyphosphate into self-standing nanopaper was developed. The fire retardant nanopaper was further incorporated into the polymer matrix, in conjunction with continuous fiber mats, through resin transfer molding process to improve fire retardant performance of structural composites. The morphology, thermal stability, and flammability of polymer composites coated with hybrid nanopaper were studied. The cone calorimeter test results indicated that the peak heat release rate of the composites coated with a CNF-clay nanopaper was reduced by 60.5%. The compact char material formed on the surface of the residues of the CNF-clay nanopaper was analyzed to understand the fire retardant mechanism of the nanopaper. The financial support from Office of Naval Research is acklowdged. nanocomposites hybrid nanopaper carbon nanofiber clay POSS xGnP flame resistance Engineering Mechanical Engineering
675	The Effect of Material and Processing on the Mechanical Response of Vapor-Grown Carbon Nanofiber/Vinyl Ester Composites Lee, Juhyeong 01 May 2010 (has links) The effects of material/fabrication parameters on vapor-grown carbon nanofiber (VGCNF) reinforced vinyl ester (VE) nanocomposite flexural moduli and strengths were investigated. Statistically reliable empirical response surface models were developed to quantify the effects of VGCNF type, use of dispersing agent, mixing method, and VGCNF loading on flexural properties. Optimal nanocomposite formulation and processing (0.74 phr oxidized VGCNFs, dispersing agent, and high-shear mixing) resulted in predicted flexural modulus and strength values 1.18 and 1.26 times those of the neat resin. Additional flexural, tensile, and compressive tests were performed for optimally configured nanocomposites cured in a nitrogen environment. While flexural and tensile moduli significantly increased with increasing VGCNF loading, the corresponding strengths fell below those of the neat resin. In contrast, nanocomposite ultimate compressive strengths significantly exceeded the neat resin strengths. Nanocomposites prepared using aggressive high-shear mixing displayed improved elastic moduli and substantially increased strengths relative to nanocomposites prepared using baseline methods. dispersion processing fabrication vapor-grown carbon nanofiber nanoreinforcement thermosets nanocomposites vinyl ester
676	Carbon Nanotubes on Carbon Fibers: Synthesis, Structures and Properties Zhang, Qiuhong 05 May 2010 (has links) No description available. Materials Science Carbon Nanotube (CNT) Carbon Fiber (CF) Nanocomposites Interface Nanoindentation Electromechanical Properties
677	Field Assisted Self Assembly for Preferential Vertical Alignment of Particles and Phases Using a Novel Roll-to-Roll Processing Line Batra, Saurabh 29 April 2014 (has links) No description available. Polymers electric field roll-to-roll birefringence directed assembly clay nanocomposites, electro-optics barium titanate capacitors
678	Development of Conductive Green Polymer Nano-Composite for use in Construction of Transportation Infrastructure Gissentaner, Tremaine D. January 2014 (has links) No description available. Civil Engineering Nanocomposites Nano-composites Carbon Nanofibers Polylactic Acid PLA Green Polymers
679	Development of Nanocomposites Using Graphene Synthesized by Solvent Exfoliation Method Wang, Weiling January 2014 (has links) No description available. Engineering nanocomposites graphene PMMA PPy solvent exfoliation conductive plastics electrical conductivity modeling
680	Glass Formation Behavior of Model Ionomers Ruan, Dihui 29 May 2015 (has links) No description available. Polymers Molecular Physics Nanoscience Physics ionomers glass nanocomposites EHM Adam-Gibbs segmental relaxation dynamics interface crosslink

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