Global ETD Search

141	Assessing the Feasibility of Poly-(3-hydroxybutyrate-co-3-hydroxyvalerate) (PHBV) and Poly-(lactic acid) for Potential Food Packaging Applications Modi, Sunny J. 25 August 2010 (has links) No description available. Polymers biomaterials thermal mechanical rheological barrier properties processing Poly (L-lactic acid) (PLA) Differential Scanning Calorimetry (DSC) Thermogravimetric Analysis (TGA)
142	Analyses of Effects of Pigments on Maxillofacial Prosthetic Material Hu, Xingxue 01 September 2010 (has links) No description available. Biomedical Research Dental Care Health Care Materials Science Physics Polymers pigments maxillofacial elastomer maxillofacial prostheses color translucency reflectance theory cytotoxicity differential scanning calorimetry
143	Crystallization and Melting Studies of Poly(ε-caprolactone) and Poly(ethylene oxide) using Flash™ Differential Scanning Calorimetry and Preparation and Characterization of Poly(δ-valerolactone) Fractions Vincent, Matthew Ryan 03 July 2019 (has links) The isothermal crystallization and melting temperatures of poly(ε-caprolactone) were correlated using fast differential scanning calorimetry. The melting kinetics was found to be independent of isothermal crystallization temperature and time. The conventional Hoffman-Weeks method could not be used to determine the equilibrium melting temperature because the observed melting temperatures were greater than the crystallization temperatures by a constant, so the Gibbs-Thomson method was used instead, yielding an equilibrium melting temperature of 103.4 ± 2.3°C. A modification was proposed to the non-linear Hoffman-Weeks equation that included a non-linear undercooling dependence for the kinetic fold surface free energy upon crystallization and permitted accurate modeling of the observed melting behavior. The isothermal crystallization rates of four narrow molecular weight poly(ethylene oxide) fractions were characterized using fast differential scanning calorimetry for crystallization temperatures spanning 100°C range with the lower limit approaching the glass transition. A transition from homogeneous to heterogeneous primary nucleation was observed at −5°C. The kinetic analysis suggested that the crystal growth geometry depends strongly on temperature, where rod-like structures begin to appear near the glass transition temperature, highly branched solid sheaves grow throughout the homogeneous primary nucleation temperature range, and spherulites grow in the heterogenous primary nucleation range. Poly(δ-valerolactone) was synthesized using microwave-assisted techniques. Narrow molecular weight fractions were obtained using successive precipitation fractionation. Preliminary isothermal crystallization studies suggest that conventional thermal analysis methods are not adequate to measure the melting temperatures accurately due to reorganization during heating. / Doctor of Philosophy / Plastics may be classified into two general categories: those which form ordered domains upon solidification, i.e. undergo crystallization, and those which remain disordered upon solidification, i.e. form glasses. This work is focused on studying the crystallization and melting processes in two linear polymers, poly(ε-caprolactone) and poly(ethylene oxide), using new experimental technology. In the case of poly(ε-caprolactone), the experimental data could not be rationalized by existing theories, and we have proposed modifications to these theories that explained the results. In the case of poly(ethylene oxide), the application of new experimental technology resulted in previously unreported data that indicated novel behavior at very low crystallization temperatures. In the last portion of this work, poly(δ-valerolactone) was made using a novel approach. Conventional experimental approaches to measuring the crystallization and melting behavior were shown to be inadequate. polymer crystallization melting kinetics fast differential scanning calorimetry poly(ε-caprolactone) poly(ethylene oxide) poly(δ-valerolactone) fold surface free energy Gibbs-Thomson Hoffman-Weeks equilibrium melting temperature
144	Laser Activated Bonding of Wood Church, William Travis 20 January 2011 (has links) It was found that laser modified wood surfaces can be bonded together to create a wood composite without the need of any additive. This bonding method removes the need of applying adhesive, potentially lowers cost, and eliminates off gassing of petroleum resins, creating a wood product with many eco-friendly attributes. This body of work outlines a) initial chemical analysis of the laser modified surface b) its bond strength and c) the optimization of factors that control the strength of the bond. Surface chemical analysis on laser modified wood was conducted using photo acoustic Fourier transform infrared spectroscopy (PA-FTIR) and X-Ray photoelectron spectroscopy (XPS). Light microscopy and scanning electron microscopy were utilized for surface topology analysis.Differential scanning calorimetry (DSC) quantified the thermal properties of the modified wood surface. Screening of multiple factors that would contribute to surface modification and adhesion was performed utilizing mechanical testing. Optimization of significant factors that affect bond strength was determined statistically utilizing a design of experiment approach. Chemical analysis of the laser modified surface revealed changes in the carbonyl and aromatic regions indicating modification of the hemicellulose and lignin components, intensifying with increasing laser modification.The C1/C2 ratios found via XPS revealed that one or more of the following is occurring: more extractives have moved to the surface, condensation reactions among lignin units, and the loss of methoxy and breakage of aryl ether linkages occurred.Microscopy images showed color changes to a darker caramel color with a smoothing of surface topology, suggesting the occurrence of the softening and/or melting of wood polymers. DSC verified chemical and/or physical changes in the wood with the modified material now having a glass transition temperature between 130-150°C.DOE found that laser parameters (power and focus) as well as hot press parameters (temperature and pressure) were significant in optimizing the bond. The impact of the study is the first documentation of the ability to laser modifies wood surfaces and subsequently bond them together. The ability of the wood polymers at the surface to undergo flow at elevated temperature is implicated in the adhesion mechanism of the laser modified wood. / Master of Science differential scanning calorimetry scanning electron microscopy light-activated Wood bonding carbon dioxide laser Design of Experiment x-ray photoelectron spectroscopy
145	The Role of Interface in Crystal Growth, Energy Harvesting and Storage Applications Ramesh, Dinesh 12 1900 (has links) A flexible nanofibrous PVDF-BaTiO3 composite material is prepared for impact sensing and biomechanical energy harvesting applications. Dielectric polyvinylidene fluoride (PVDF) and barium titanate (BaTiO3)-PVDF nanofibrous composites were made using the electrospinning process based on a design of experiments approach. The ultrasonication process was optimized using a 2k factorial DoE approach to disperse BaTiO3 particles in PVDF solution in DMF. Scanning electron microscopy was used to characterize the microstructure of the fabricated mesh. The FT-IR and Raman analysis were carried out to investigate the crystal structure of the prepared mesh. Surface morphology contribution to the adhesive property of the composite was explained through contact angle measurements. The capacitance of the prepared PVDF- BaTiO3 nanofibrous mesh was a more than 40% increase over the pure PVDF nanofibers. A comparative study of dielectric relaxation, thermodynamics properties and impact analysis of electrospun polyvinylidene fluoride (PVDF) and 3% BaTiO3-PVDF nanofibrous composite are presented. The frequency dependent dielectric properties revealed micro structural features of the composite material. The dielectric relaxation behavior is further supported by complex impedance analysis and Nyquist plots. The temperature dependence of electric modulus shows Arrhenius type behavior. The observed non-Debye dielectric relaxation in electric loss modulus follows a thermally activated process which can be attributed to a small polaron hopping effect. The particle induced crystallization is supported with thermodynamic properties from differential scanning calorimetric (DSC) measurements. The observed increase in piezoelectric response by impact analysis was attributed to the interfacial interaction between PVDF and BaTiO3. The interfacial polarization between PVDF and BaTiO3 was studied using density functional theory calculations and atomic charge density analysis. The results obtained indicates that electrospinning offers a potential way to produce nanofibers with desired crystalline nature which was not observed in molded samples. In addition, BaTiO3 can be used to increase the capacitance, desired surface characteristics of the PVDF nanofibers which can find potential application as flexible piezoelectric sensor mimicking biological skin for use in impact sensing and energy harvesting applications. Polyvinylidene fluoride (PVDF) Barium titanate (BaTiO3) Ultrasonication Electrospinning Design of experiments (DoE) Relaxation Interfaces Dielectric properties Differential scanning calorimetry (DSC) Piezoelectricity Impact sensing Electronic structure calculations.
146	Ultrasonic Processing of Aluminum 2139 and 7050 Reed, Jordan Derek 08 1900 (has links) Acoustics is the study of all sound waves, with ultrasound classified as those frequencies above 20,000 Hz. Currently, ultrasound is being used in many industries for a variety of purposes such as ultrasonic imaging, ultrasonic assisted friction stir welding, and ultrasonic spot welding. Despite these uses, the effects of ultrasound on phase stability and resultant mechanical properties has been minimally analyzed. Here we study the impact waves play in ultrasonic welding and design an apparatus to maximize waves entering aluminum alloy samples. Aluminum 2139 and 7050 are used because they are precipitation strengthened by metastable phases so temperature change, and the corresponding phase stability, can greatly impact their strength. Results suggest that the ultrasonic welder primarily imposes a localized temperature spike due to friction, averaging over 200°C in a few seconds, which generally lowers the Vickers hardness due to coarsening or even dissolution of strengthening precipitates. Conversely, the new design increases the Vickers hardness by up to 30% over the initial hardness of approximately 63HV for aluminum 2139 and 83HV for aluminum 7050, respectively, while only increasing the temperature by an average of approximately 10°C. This new design was unable to achieve peak hardness, but the strengthening it achieved in two minutes was equivalent to one month of natural aging. If this system was able to be fine-tuned, it could serve as a quick strengthening process for recently weakened aluminum alloys, such as after friction stir welding. Ultrasonic Aluminum alloys Aluminum 2139 AA2139 Aluminum 7050 AA7050 Precipitation Strengthened Vickers Hardness DSC 20 kHz 20000 Hz ultrasonic spot welder differential scanning calorimetry Aluminum alloys. Ultrasonic welding.
147	Ternary organic–inorganic nanostructured hybrid materials by simultaneous twin polymerization Weißhuhn, J., Mark, T., Martin, M., Müller, P., Seifert, A., Spange, S. 06 March 2017 (has links) (PDF) The acid and base catalyzed simultaneous twin polymerization (STP) of various 2,2′-disubstituted 4H-1,3,2-benzodioxasiline derivatives 2a–d with 2,2′-spirobi[4H-1,3,2-benzodioxasiline] (1) are presented in this paper. The products are nanostructured ternary organic–inorganic hybrid materials consisting of a cross-linked organic polymer, silica and a disubstituted polysiloxane. It can be demonstrated whether and in which extent the copolymerization of the two inorganic fragments of 1 and 2 takes place among the STP and how the molar ratio of the two components determines the structure formation of the resulting hybrid material. Steric and electronic effects of the substituents at the silicon center of 2 on the molecular structure formation and the morphology of the resulting hybrid material were investigated by means of solid state CP MAS 29Si and 13C NMR spectroscopy as well as high-angle annular dark-field scanning transmission electron microscopy (HAADF-STEM). The mechanical properties (hardness and Young's modulus) of the hybrid materials were analyzed by means of nanoindentation measurements. / Dieser Beitrag ist aufgrund einer (DFG-geförderten) Allianz- bzw. Nationallizenz frei zugänglich. Nanostrukturen Zwillingspolymerisation Organisch-anorganische Hybridmaterialien DSC Silicium-Spiroverbindung Phenolharz nanostructure twin polymerization organic-inorganic hybrid material DSC silicon monomer phenolic resin ddc:540 Nanostruktur Sol-Gel-Verfahren Organisch-anorganischer Hybridwerkstoff Differential scanning calorimetry Siliciumdioxid Siloxane Phenoplast
148	Synthèse et caractérisation de complexes métalliques de ruthénium, fer et cobalt à base des ligands terpyridine et bipyridine pour l'obtention de cristaux liquides Ménard-Tremblay, Pierre January 2008 (has links) Mémoire numérisé par la Division de la gestion de documents et des archives de l'Université de Montréal. Métallomésogenes Cristaux liquides Complexes de ruthénium Complexes de fer Complexes de cobalt Diffraction à balayage Diffraction des rayons-X Microscopie optique polarisante Metallomesogens Liquid crystal Ruthenium complexes Iron complexes Cobalt complexes Differential scanning calorimetry X-ray diffraction Polarized optical microscopy
149	Modification des propriétés physico-chimiques de l'amidon par procédés hydrothermiques : Contribution à l'étude des transferts couplés chaleur-masse / Physico-chemical modifications of starch by hydrothermal processes : Contribution to the investigation of simultaneous heat and mass transfer Bahrani, Seyed Amir 01 June 2012 (has links) L’amidon, biopolymère de réserve, composant majeur des céréales et des plantes de grande culture, trouve de nombreuses applications industrielles après transformation hydrothermique. L’objectif de la thèse est d’étudier les modifications des propriétés structurales et fonctionnelles de l’amidon de maïs standard modifié par traitement physique, de type hydrothermique à l’aide de trois procédés. L’intensification des traitements, dans un contexte où le développement durable apparaît comme une priorité majeure, s’inscrit dans la large thématique de la valorisation des agro-ressources et du développement des procédés de transformation consacrés aux ressources carbonées renouvelables. La caractérisation des modifications des propriétés physicochimiques de l’amidon,générées par les traitements a été réalisée, dans l’objectif de relier les différences aux comportements thermique(transitions de phase, empesage) et rhéologique (comportement à l’écoulement et viscoélasticité) des amidons hydrotraités. Les traitements physiques appliqués aux amidons ont conduit à des modifications plus ou moins importantes de leurs structures. La maîtrise de l’utilisation de l'amidon nécessite la bonne connaissance des transitions de phase impliquées et des structures résultantes, fonction principalement de la teneur en eau et de la température. Dans cet objectif, une partie des travaux de thèse a été consacrée à la compréhension des phénomènes physiques à l’origine des transferts de matière et de chaleur dans le matériau amylacé pendant son hydrotraitement, ainsi que les équations régissant ces transferts. Un modèle phénomènologique de transfert couplé de masse et de chaleur a été développé, tenant compte des réactions biochimiques qui ont lieux simultanément dans le matériau, en présence d’eau et de chaleur. Les résultats de la modélisation numérique, à l’aide de la méthode des éléments finis, a permis de définir la répartition spatiale, des paramètres variables(température, teneur en eau,…), dont l’influence est déterminante sur la progression des réactions de fusion. / Starch, biopolymer of reserve, is the major component of cereals and of crop plants, has many industrial applications after hydrothermal processes. The objective of this work is to study the structural and function almodifications of standard maize starch by physical processes, as hydrothermal treatments (action of heat and moisture). The intensification of treatments, in a context of sustainable development, is nowadays a major challenge. This action belongs to the themes linked to the agri-resources valorisation and the development of the transformation processes devoted to the renewable carbonaceous resources. The impact of hydrothermaltreatments on starch physicochemical properties is extensively studied with the aim to connect the modificationof hydrotreated starches to their thermal (phase transitions, pasting) and rheological (flow and viscoelasticity)behaviours. The physical treatments applied to starches lead to important modifications of their structures,according to the processing conditions. The mastering of starch use requires the knowledge of implied phase transitions and resulting structures, which are mainly function of water content and temperature. In this aim, apart of this work was devoted to the comprehension of the physical phenomena responsible of the heat and mass transfer in the starch layer, during the treatment. A coupled heat and mass transfer model was developed, taking into account the biochemical reactions, which take place in the material simultaneously in presence of water and heat. Using the finite element method, the numerical simulation allowed to define the space distribution of the variable parameters (temperature, water content,…), which have a great influence on the progression of fusion reactions. Amidon Procédé Hydrothermique Diffraction par rayon X Analyse Enthalpique Différentielle Rhéologie Propriétés Thermophysiques Modélisation Simulations Numériques Starch Hydrothermal Process X-Ray Diffraction Differential Scanning Calorimetry Rheological Properties Thermophysical Properties Modelisation Numerical Simulation
150	Étude des propriétés membranaires des vésicules lipidiques incorporant des triterpènes oxygénés bioactifs d'origine végétale : application à la cucurbitacine E et à l'érythrodiol / Membrane properties of lipid vesicles incorporating natural triterpenic bioactive molecules : application to cucurbitacin E and erythrodiol Habib, Lamice 04 February 2014 (has links) La cucurbitacine E et l'érythrodiol sont des triterpènes naturels oxygénés ayant respectivement un squelette tétra et pentacyclique. Ils sont reconnus pour leurs diverses propriétés biologiques. Dans ce travail de thèse, nous étudions leur interaction avec les membranes des vésicules lipidiques dans le but de mieux comprendre leur pharmacodynamie. Nous avons préparé des liposomes en absence et en présence de la cucurbitacine E et de l'érythrodiol par les techniques d'évaporation en phase inverse suivie d'une extrusion, d'hydratation du film lipidique et d'injection d'éthanol. Les caractéristiques physicochimiques des vésicules lipidiques incorporant ou non la molécule triterpénique ont été étudiées par des techniques adéquates. Les analyses de la cucurbitacine E et de l'érythrodiol par la chromatographie liquide à haute performance ont montré que leurs taux d'incorporation dans les liposomes sont élevés. Les mesures de taille obtenues par la diffusion dynamique de la lumière ont démontré que les liposomes incorporant les triterpènes présentent une taille moyenne inférieure à celle des liposomes témoins. Les images obtenues par la microscopie électronique à transmission ont confirmé la formation de vésicules sphériques. Les mesures des dimensions des vésicules observées par la microscopie à force atomique (AFM), ont révélé que les liposomes incorporant la cucurbitacine E sont plus hauts et résistent mieux à la force exercée par la pointe AFM que les liposomes témoins. Par ailleurs, les liposomes incorporant l'érythrodiol sont plus fragiles que les liposomes témoins et ont tendance à éclater en bicouches lipidiques à la surface du support. Les courbes thermiques obtenues par la calorimétrie différentielle à balayage ont permis de conclure que la cucurbitacine E est localisée à l'interface polaire-apolaire de la membrane liposomiale alors que l'érythrodiol s'insère entre les chaînes acyles des phospholipides et aboutit à la formation des domaines hétérogènes au niveau de la membrane. La cinétique de libération de la sulforhodamine B, mesurée par la spectroscopie de fluorescence, a révélé que la membrane liposomiale devient, en présence de la cucurbitacine E, plus perméable à la sulforhodamine B incorporée dans la phase aqueuse interne. L'ensemble des résultats suggère que la cucurbitacine E et l'érythrodiol interagissent avec la membrane lipidique et affectent ses propriétés physico-chimiques. Leur effet sur la membrane ne semble pas être similaire. Des études ultérieures impliquant d'autres triterpènes sont envisagées pour identifier le (s) motif (s) structural (aux) et les paramètres physico-chimiques régissant leur interaction et localisation membranaire / Cucurbitacin E and erythrodiol are natural oxygenated triterpenes having respectively, a tetra and pentacyclic skeleton. They are known for their numerous biological properties. In this thesis, we studied their interaction with the membranes of lipid vesicles to better understand their pharmacodynamics. We have prepared liposomes in the absence and presence of cucurbitacin E and erythrodiol using the reverse phase evaporation technique followed by extrusion, the hydration of lipid film and the ethanol injection techniques. The physicochemical characteristics of lipid vesicles incorporating or not the triterpenic molecules were investigated by appropriate techniques. The determination of cucurbitacin E and erythrodiol in the vesicles by high performance liquid chromatography showed high incorporation efficiencies of both triterpenes. Size measurements obtained by dynamic light scattering showed that liposomes incorporating triterpenes were smaller than empty liposomes. The images obtained by transmission electron microscopy confirmed the formation of spherical vesicles. Measurements of vesicles dimensions by atomic force microscopy (AFM) demonstrated that liposomes incorporating cucurbitacin E were higher and more resistant to the force exerted by the AFM tip than the blank liposomes. Liposomes incorporating erythrodiol were more fragile and tend to break up into lipid bilayers on the mica surface. Results obtained by differential scanning calorimetry suggested that cucurbitacin E is localized at the polar-apolar interface of the liposomal membrane while erythrodiol is inserted between the acyl chains of the phospholipids leading to the formation of heterogeneous lipid domains. The release kinetics of the sulforhodamin B encapsulated into the aqueous phase and measured by fluorescence spectroscopy revealed that the liposomal membrane becomes in the presence of cucurbitacin E, more permeable to this probe. The overall results suggest that cucurbitacin E and erythrodiol affect differently Cucurbitacine E Érythrodiol Liposomes Diffusion dynamique de la lumière Microscopie à force atomique Spectroscopie de fluorescence Cucurbitacin E Erythrodiol Liposomes Differential scanning calorimetry Dynamic light scattering Atomic force microscopy Transmission electron microscopy Fluorescence spectroscopy 615

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