Global ETD Search

151	Réaction d'alcénylation d'halogénures d'alkyles et de carbo-alcénylation d'oléfines / Alkenylation reaction of alkyl halides and carboalkenylation of olefins Chaambi, Ahmed 13 December 2018 (has links) L’objectif de ces travaux de thèse a consisté en le développement de nouveaux accepteurs radicalaires de type vinylsulfoxydes et vinylsulfoximines pour la mise en œuvre de processus multicomposants radicalaires. Ces réactions de carbo-alcénylation d’oléfines permettent l’accès à des substrats comportant plusieurs fonctionnalités utiles en synthèse organique et la formation de plusieurs liaisons carbone-carbone en un seul pot. L’absence de contrôle de la stéréochimie du centre asymétrique créé lors de la dernière étape élémentaire du processus multi-composants constitue l’un des derniers problèmes à résoudre dans cette méthodologie. Nous avons, étudié le développement de réactions multicomposants radicalaires impliquant des précurseurs vinylsulfoxydes et sulfoximines. Lors de ces processus, les produits de carboalcénylations d’oléfines ont été obtenus avec des rendements moyens à bons. Nous avons développé en parallèle une méthode efficace pour l’alcénylation directe photocatalysée d’hétérocycles oxygénés par activation de liaisons Csp3 -H à l’aide d’une quantité catalytique de diarylcétone sous irradiation UV. Ce processus permet notamment un accès aisé aux dioxanes substitués par un groupement alcényle, avec un rendement élevé. Une approche énantiosélective de ce processus a également été réalisée. Dans une derniére partie, nous avons développé une stratégie sans étain qui utilise le diphenyliodonium hexafluorophosphate pour réaliser la vinylation des halogénures d'alkyle dans des conditions radicalaires. Le diphenyliodonium hexafluorophosphate est donc considéré comme un substitut efficace de l'étain dans ce processus de radical libre. / The aim of this thesis was to develop new radical acceptors including vinylsulfoxides and vinylsulfoximines for the implementation of radical multicomponent processes. These carbo- alkenylation reactions of olefins allow access to substrates having several functionalities, which are useful in organic synthesis and the formation of several carbon-carbon bonds in a single pot. The lack of control of the stereochemistry of the stereogenic center, created during the last elementary stage of the multi-component process, is one of the key problems to be solved in this methodology. We have studied the development of radical multicomponent reactions involving vinylsulfoxide and sulfoximine precursors. In these processes, the olefin carbo-alkenylation products were obtained in moderate to good yields. We have developed in parallel an efficient method for the direct photocatalyzed alkenylation of oxygenated heterocycles through the activation of a Csp3 –H bond, using a catalytic amount of a diarylketone under UV irradiation. This process provides an easy access to alkenyl-substituted dioxanes in high yield. An enantioselective version of this process was also studied. In the final part, we developed a tin-free strategy that uses diphenyliodonium hexafluorophosphate tovinylate alkyl halides under free radical conditions. Diphenyliodonium hexafluorophosphate is thereforeconsidered as an efficient tin surrogate in this free-radical process. Réactions multicomposants radicalaires Carbo-alcénylation Alcénylation Vinylation Sulfoxyde Sulfoximine Chimie radicalaire sans étain Multicomponent radical reactions Carbo-Alkenylation Alkenylation Vinylation Sulfoxide Sulfoximine Tin-free radical chemistry
152	Enzymatically initiated synthesis of biomimetic receptors based on molecularly imprinted polymers by free radical polymerization / Synthèse de récepteurs biomimétiques basés sur les polymères à empreintes moléculaires par polymérisation radicalaire libre initiée par catalyse enzymatique Daoud Attieh, Mira 01 April 2016 (has links) Depuis de nombreuses années, l’utilisation d’enzyme pour la synthèse de polymères naturels ou synthétiques a largement été développée en tant que procédé alternatif plus vert et plus respectueux de l’environnement. En effet, comparée aux méthodes conventionnelles de synthèse, les enzymes offrent une sélectivité élevée, une capacité à réagir dans des conditions de réaction douces, ainsi que la possibilité de recyclage du biocatalyseur. D’autre part, les polymères à empreintes moléculaires (MIPs) sont des matériaux synthétiques avec des propriétés de reconnaissance moléculaire spécifique envers une molécule cible. Récemment, les MIPs ont été utilisés dans les applications environnementales et biomédicales de part leur propriétés de reconnaissance moléculaire, leur spécificité et sélectivité. Cependant, leur application reste limitée en raison de leur faible biocompatibilité et de la présence de résidu de polymérisation potentiellement nocif. Ce travail de thèse a pour objectif de proposer une méthode alternative pour la synthèse de MIPs basée sur le concept de chimie verte. La peroxydase de raifort (HRP) est utilisée pour initier la co-polymérisation en milieux aqueux de monomères fonctionnels méthacrylates et d’agents réticulants en catalysant la génération des radicaux libres. Différents hydrogels ont été synthétisés et caractérisés, en particulier une cytotoxicité plus faible a été obtenue comparée à celle des polymères synthétisés traditionnellement. La synthèse a été optimisée afin de pouvoir contrôler la taille des particules et le rendement de polymérisation. Des MIPs sous forme de nanoparticules ont été préparés en milieu aqueux pour plusieurs molécules de faible poids moléculaire ainsi que pour des protéines par polymérisation radicalaire libre initiée par HRP. L’effet de la méthode d’initiation a été évalué en comparant les propriétés de ces MIPs à ceux préparées par les méthodes traditionnellement. L’immobilisation de l’HRP a été aussi effectuée pour synthétiser des hydrogels et des MIPs. L’enzyme immobilisée a pu être réutilisée pour synthétiser des MIPs avec les mêmes performances en termes de morphologie, rendement, spécificité et sélectivité. Ces nouveaux matériaux offrent de nombreuses perspectives pour des applications environnementales et biomédicales. / Enzyme-catalyzed synthesis of natural and synthetic polymers has been developed since several decades, as an eco-friendly process. Compared to the conventional methods, enzymes offer high selectivity, ability to operate under mild conditions and to recycle the catalyst. On the other hand, molecularly imprinted polymers (MIPs) are synthetic materials with specific recognition properties for target molecules. They have recently attracted increasing attention in environmental and newly in biomedical applications for their specificity and selectivity. However, concerns about MIP toxicity for human and environment safety are of great importance. Herein, carrying forward the concept of green chemistry, an enzyme-mediated synthesis approach is described to prepare molecularly imprinted nanoparticles (MIP-NPs) in aqueous media. Horseradish peroxidase (HRP) is used to initiate the polymerization of methacrylate-based monomers and cross-linkers by catalyzing the generation of free radicals. Different hydrogels are synthesized and characterized. “Greener” hydrogels are obtained with lower cytotoxicity than that of polymers synthesized by traditional way. The hydrogels synthesis is optimized in order to control the particles sizes and polymerization yields. Moreover, water-compatible MIP nanoparticles for the recognition of different small molecules and proteins are prepared in aqueous media by HRP-initiated free radical polymerization and compared to MIPs prepared by the thermal or photopolymerization methods. HRP immobilization is also performed for hydrogels synthesis as well as MIP preparation. The reusability of immobilized enzyme is investigated for the preparation of several MIP batches with the same morphology, yield as well as good specificity and selectivity. We believe that this new synthesis method for MIPs will provide new opportunities to enlarge the use of molecular imprinting technology in biomedical and environmental applications. Hydrogel Polymérisation radicalaire libre Catalyse enzymatique Peroxydase de raifort Chimie verte Molecularly imprinted polymers Water-compatible nanoparticles Free radical polymerization Enzymatic catalysis Horseradish peroxidase (HRP)
153	Síntese de látices hibridos de poliestireno e argila montmorilonita pelos mecanismos de polimerização via radical livre em emulsão e miniemulsão / Synthesis of polystyrene and montmorillonitic clay hybrid latexes by free radical emulsion and miniemulsion polymerization. Fatima Cristina Torres de Souza 17 September 2010 (has links) Materiais nanocompósitos híbridos polímero-argila nos quais lamelas nanométricas de argila montmorilonita são encapsuladas e dispersas em matriz polimérica são em geral mais rígidas, tenazes e resistentes do que os materiais poliméricos convencionais e tem o potencial de aplicações em revestimentos e filmes com propriedades de barreira. Dentre as várias técnicas de preparação de nanocompósitos poliméricos, as técnicas de polimerização \"in-situ\" em emulsão e mini-emulsão vem sendo empregada na síntese de látices híbridos com lamelas de argilas encapsuladas pelo polímero. Neste trabalho foram preparados látices híbridos de poliestireno e argila montmorilonita esfoliada através de dois métodos: no primeiro, a polimerização em emulsão e miniemulsão convencional na presença de argila modificada com sal quaternário de amônio é realizada com surfatante catiônico; no segundo método, um surfatante aniônico reativo foi usado para modificar uma argila natural sódica e empregada na polimerização em emulsão. Os resultados obtidos tanto para a polimerização em emulsão como em miniemulsão empregando idênticos reagentes (argila organofílica modificada e surfatante catiônico) mostraram boa conversão, aumento na velocidade de polimerização com aumento da concentração de surfatante e de argila, aumento na temperatura de pico na máxima velocidade de decomposição (TG), aumento no módulo de armazenamento no patamar vítreo e no patamar borrachoso (DMTA) com aumento da concentração de argila, encontrando um valor mínimo em ambos a 5% de argila. Apesar dessas características positivas, não foi obtida a encapsulação das lamelas da argila que era o objetivo principal do trabalho. Por outro lado, o método de polimerização em emulsão não convencional com surfatante reativo mostrou baixa eficiência na conversão mas que se mostrou eficaz na encapsulação das lamelas da argila para os látices com baixa conversão e elevado diâmetro de partícula. / Polymer-clay nanocomposite materials, in which nanometer-thick layers of clay dispersed in polymers, are generally stiffer, stronger, and tougher than normal polymeric materials and can be potentially useful in a variety of applications. These polymer-clay nanocomposites can be prepared in several ways, namely by emulsion \"in-situ\" polymerisation where polymer chains are coagulated on silicate layers producing capped silicate layers are more or less uniformly dispersed in aqueous medium. The objective of this work is to prepare polymer-clay hybrid latexes with exfoliated clay platelets encapsulated inside latex particles in order to improve the exfoliation of the clay platelets in the final polymeric film. To achieve this objective two separate approaches have been investigated, first by conventional emulsion polymerization and miniemulsion polymerization in the presence of montmorillonite clay modified by cationic surfactant and in the other approach a reactive anionic surfactant was used to modify the natural montmorillonite clay layers by emulsion polymerization. The results for both the emulsion polymerization as in miniemulsion using identical reagents (organoclay modified and cationic surfactant) showed good conversion, polymerization rate increased with increasing concentration of surfactant and clay, increased peak temperature at maximum speed decomposition (TG), an increase in storage modulus in the glassy plateau and the rubbery plateau (DMTA) with increasing concentration of clay, finding a minimum value in both the 5% clay. Despite these positive characteristics, encapsulation was not obtained from lamellar clay that was the main objective. Moreover, the method of emulsion polymerization with non-conventional reactive surfactant showed low conversion efficiency but has proved effective in the encapsulation of the lamellae of the clay for the lattices with low conversion and high particle diameter. Látex híbrido Nanocompósito polímero/argila Polimerização via radical livre Emulsion and miniemulsion polymerization Free radical polymerization Hybrid latex Polymer/clay nanocomposite
154	Cinética de polimerização avaliada por método rigoroso. / Free-radical polymerization kinetics solved by rigorous computation. Edoardo Melloni 14 July 2014 (has links) A distribuição de pesos moleculares (DPM) de um polímero afeta as propriedades mecânicas, térmicas e reológicas do material. Além disso, a análise em tempo real de uma reação de polimerização é uma tarefa complicada e, consequentemente, os procedimentos de controle devem ser baseados em valores gerados pelos modelos. Por isso, é extremamente importante ter dados confiáveis sobre distribuições de pesos moleculares, melhorar a eficiência dos métodos existentes e desenvolver novos métodos capazes de prever as heterogeneidades das reações de polimerização. Experimentalmente, a DPM pode ser obtida usando técnicas como a cromatografia de permeação em gel. Para predizer a DPM, vários métodos foram desenvolvidos nas ultimas décadas. Um dos principais é o dos momentos estatísticos, baseado em conceitos puramente estatísticos, que não conseguem descrever completamente a DPM. Além disso, as aproximações com método de Galerkin usam polinômios ortogonais - no caso especifico polinômios de Laguerre - cujos coeficientes são calculados empregando os momentos estatísticos e a distribuição é gerada resolvendo um número de equações definido pelo usuário, relacionado à precisão desejada. Enfim, o método das funções geradoras de probabilidades foi utilizado para prever as DPMs, porém necessitando uma inversão da transformada de Laplace, que introduz problemas numéricos nem sempre possíveis de serem resolvidos. No presente trabalho, o sistema rigoroso de equações diferenciais ordinárias foi resolvido, com objetivo de reduzir as imprecisões e as limitações introduzidas pelas aproximações. Obter diretamente a DPM completa requer a resolução de um sistema contendo cerca de 2Nmax até 3Nmax equações diferenciais ordinárias rígidas, tarefa que há alguns anos era inviável devido a limitações relacionadas à capacidade de cálculo. Foi modelada a DPM para uma reação de polimerização radicalar livre de estireno e de metacrilato de metila. Um interesse especial foi dado à taxa de terminação que é, no momento, um dos temas mais investigados em polimerização por radicais livres. Os resultados das simulações foram comparados com dados experimentais tirados de reatores convencionais e, subsequentemente, com dados experimentais provenientes de um millireactor não convencional. / It is well known that the molecular weight distribution (MWD) of a synthetic polymer affects its mechanical, thermal and rheological properties. Furthermore, the on-line analysis for polymerization reaction is a difficult task and, consequently, the control procedures must rely on values given by models. As such, it is extremely important to have reliable data on the MWD, improve the efficiency of existing methods and develop new ones to predict the heterogeneities of polymerization reactions. Experimentally, the MWD can be obtained using techniques such as Gel Permeation Chromatography (GPC). To predict the MWD, many methods have been developed over the last decades. One of the main methods is the statistical moment treatment, which is based on a pure statistical concept and do not describe the whole MWD. Moreover, Galerkin approximation uses orthogonal polynomials -in general Laguerre polynomials- whose coefficients are calculated exploiting the statistical moment definition and the distribution is generated by solving a user-defined number of equations based on the desired precision. Finally, probability-generating functions that have been used to predict MWDs require Laplace transforms inversions, introducing numerical issues that must be bypassed and are not always solvable. It has been decided to base the approach without adopting any of these methods but directly solving the rigorous ordinary differential equation (ODE) system in order to reduce the inaccuracies and the limitations introduced by approximations. The direct obtention of the MWD requires the resolution of a system containing approximately 2Nmax up to 3Nmax stiff ODE equations that, a few years ago, was unfeasible due computational time limitations. The MWDs for a free radical styrene polymerization system and a methyl methacrylate system have been modeled. A special focus was given to the termination rate constant, which is, at the present, one of the most investigated topics in free radical polymerization. The results of the simulations were compared to experimental data taken from conventional reactors and, subsequently, to experimental data coming from an unconventional millireactor. Distribuição de pesos moleculares Efeito gel Efeito norrish trommsdorff Integração direta Polimerização radicalar livre Direct integration Free-radical polymerization Gel effect Molecular weight distribution Norrish trommsdorff effect Polymer science
155	Recouvrements à base de dextrane pour applications médicales / Dextran-based coatings for medical applications Michel, Eléonore 13 April 2016 (has links) L’ingénierie des biomatériaux a connu un essor prodigieux ces dernières décennies passant de matériaux simples à des structures plus complexes, particulièrement dans le domaine cardiovasculaire. Cette évolution découle de la nécessité des biomatériaux de permettre la synergie de différentes propriétés, dépendantes de leurs fonctions, qui ne sont pas forcément toutes compatibles. Historiquement, les premiers matériaux utilisés dans la conception de dispositifs médicaux étaient ceux présentant le meilleur compromis entre les propriétés physico-chimiques, mécaniques et biologiques que nécessitait leur application. Cependant, il se peut que le dispositif possède les bonnes propriétés physico-chimiques ou mécaniques, mais que sa biocompatibilité soit insuffisante induisant ainsi des complications cliniques. Afin d’améliorer ces propriétés biologiques tout en conservant les propriétés de volume du matériau, une solution est d’en modifier la surface. L’utilisation d’un revêtement permet alors de moduler la réponse biologique à l’interface biomatériau-hôte et de diminuer les effets indésirables. Ces revêtements sont optimisés selon deux critères principaux : la réponse biologique et la réponse mécanique. Pour la réponse biologique, les deux approches principales sont de mettre au point des revêtements proactifs qui engendrent l’adhérence, laprolifération ou la migration cellulaire, ou passifs, qui, principalement, sont inertes et empêchent l’adhérence de composés biologiques. Des revêtements plus complexes utilisent les deux approches permettant l’adhérence spécifique de certainescellules tout en empêchant l’adhérence d’autres composants biologiques. Cette pratique est très utile pour lutter contre la resténose, complication survenant après opération de l’athérosclérose qui obstrue les vaisseaux sanguins. Une pratique courante est la pose d’un stent qui permet d’ouvrir l’artère de nouveau et de rétablir le flux sanguin. Le phénomène de resténose obstrue de nouveau le vaisseau sanguin, majoritairement par la prolifération incontrôlée de cellules musculaires lisses. La recherche sur les revêtements contre la resténose vise à inhiber la prolifération de ces cellules tout en facilitant la ré-endothélialisation. Les revêtements permettraient alors, à la fois de favoriser l’adhérence et la prolifération de cellules endothéliales et de limiter celles des cellules musculaires lisses à la surface du stent ou en limitant toute adhérence non-spécifique. Il a été démontré lors d’études précédentes qu’un copolymère à base de dextrane et de poly(méthacrylate debutyle) (PBMA) répondait à ces critères biologiques et qu’il possédait en plus une bonne résistance à la déformation, paramètre important lié à la déformation induite lors de l’implantation d’un stent. L’approche de ce projet était d’utiliser ce copolymère comme revêtement de stent et d’en améliorer la stabilité à long terme en formant des liens covalents avec le substrat. Pour ce faire, cela nécessitait l’activation de la partie dextrane du copolymère afin de pouvoir le greffer au substrat. Il était important de vérifier pour chaque étape l’influence des modifications effectuées sur les propriétés biologiques et mécaniques des matériaux obtenus, mais aussi d’un point de vue de la chimie, l’influence que cette modification pouvait induire sur la réaction decopolymérisation.... / The last decades have witnessed the remarkable growth of biomaterial science and engineering field, especiallyfor cardiovascular applications, for which devices have evolved from simple material to complex structures.This development has stemmed from the necessity for biomaterials to exhibit different properties, related totheir function, which are not always inherently compatible. Historically, the first materials selected for medicaldevices conception were the ones exhibiting the best compromise between all the physicochemical, mechanicaland biological requirements. Nevertheless, while physicochemical and mechanical properties are often handilycombined, the development of materials which also possess suitable biological properties have proved to bemuch more challenging, leading to clinical complications.Surface modification represents a valid solution to improve the biological performances of medical deviceswhile maintaining the bulk properties of the material. Biomaterial coatings may modulate the biologicalresponse at the biomaterial-host interface and decreases the undesirable effects. Coatings have been optimizedin regards to two main aspects: the biological response and the mechanical response. For the biologicalresponse, the two main approaches consist in 1) inducing cell adhesion, proliferation or migration with proactivecoatings and 2) using inert material, mostly, and avoiding the adhesion of any biological componentswith passive coatings.More complex coatings include the two approaches, allowing the adhesion of a specific type of cell whilerepelling other biological components adhesion. This method has been very useful against the restenosisphenomenon which obstructs blood vessels. A common practice is vessel stenting, a procedure that enables thereopening of the vessel and the restoration of the blood flow. Restenosis causes the new narrowing of the vessel,mostly due to uncontrolled smooth muscle cell proliferation. Researchers looked for coatings capable oflimiting the restenosis occurrence by inhibiting this cell proliferation along with facilitating the reendothelialization.Thus, the coatings would be able to improve endothelial cells adhesion and proliferation andto inhibit smooth muscle cells ones as well as avoiding non-specific adhesion.Previous studies showed that a copolymer made of dextran and poly(butyl methacrylate) (PBMA) demonstratedsuch biological properties and a good resistance to deformation, which is an important parameter related to thedeformation implied in a stent implantation. In this work, the approach was to use this copolymer as a stentcoating and to increase its long-term stability by providing covalent bonds with the substrate. To do so, thedextran part of the copolymer firstly needed to be activated in order to be grafted to the surface. Thus, it wasimportant to ascertain the influence of the multiple modifications on the biological and mechanical propertiesof the resulting materials at each step, but also towards a chemical point of view, the influence that thesemodifications may have on the subsequent copolymerization. Carboxyméthyldextrane Mobilisation de surface Revêtements de dextrane Cellules endothéliales Cellules musculaires lisses Propriétés antithrombogènes Free radical copolymerization Endothelial cells Surface grafting Mechanical deformation
156	Synthesis of New lonic Functional Polymers by Free Radical Polymerization via the RAFT Process Baussard, Jean-François 26 January 2004 (has links) Within the emerging methods of controlled free radical polymerization, the Reversible Addition-Fragmentation chain Transfer (RAFT) process has been recently established as a powerful technique to synthesize standard polymers with controlled characteristics (narrow polydispersity and predictable molar masses). This method is now employed to synthesize well-defined, reactive precursor polymers that are subsequently converted into speciality polymers such as fluorescent-labeled polycations. Those are suitable for Electrostatic Self-Assembly (ESA). The observation of the Förster Resonance Energy Transfer (FRET) in such films is established, contributing to the understanding of the self-organization during thin film growth. The RAFT process using Benzyl Dithiobenzoate (BDTB) is shown to enable the control of the free radical polymerization of vinylbenzyl chloride (VBC). The high tolerance of the method to functional groups allows the preparation of such reactive polymers with narrow polydispersities and predictable molar masses. The well-defined precursors are easily converted, for instance, to polycations. Also they are easily functionalized by fluorophores, here derived from coumarin and perylene. The fluorophores, as pendent side chains, served as label to investigate the alternating deposition process, while the influence of molecular variations on the self-assembly can be systematized. Furthermore, when using complementary fluorophores, Fluorescence Resonance Energy Transfer (FRET) studies in organized media become possible. The alternating deposition cycles are followed by UV-Vis spectroscopy, ellipsometry, and X-Ray reflectivity. Regular growth is observed for three complementarily labeled polycations. Noteworthy, fluorescence and UV-Vis studies reveal the formation of large fluorescent dye aggregates for one coumarin and for the perylene derivative in the ESA multilayers. When these polycations are used in mixed thin films, Förster Resonance Energy Transfer (FRET) between fluorophores is observed. The non-radiative nature of the different energy transfer was confirmed by fluorescence decay time measurements/ Parmi les récentes méthodes pour contrôler la polymérisation radicalaire, le procédé RAFT (Reversible Addition-Fragmentation chain Transfer) a été récemment établi et s'impose comme une méthode performante pour la synthèse de polymères standards possédant des caractéristiques contrôlées (faibles polydispersités et masses molaires prédictibles). Cette méthode est désormais utilisée pour la synthèse de précurseurs réactifs bien définis qui sont par la suite convertis en polymères spécialisés, par exemple en polycations marqués a l'aide de sondes fluorescentes. Ces polycations peuvent être ensuite auto-assemblés électrostatiquement afin d'élaborer des films minces. Le phénomène de transfert de fluorescence (Förster Resonance Energy Transfer –FRET-) dans de tels films a été établi, contribuant par là-même à une meilleure compréhension du phénomène d'auto-organisation durant la croissance des films. Le procédé RAFT, utilisant le dithiobenzoate de benzyle (BDTB), a démontré sa capacité à contrôler la polymérisation radicalaire du chlorométhlstyrène (VBC). La tolérance de cette méthode vis à vis des groupes fonctionnels permet la synthèse de polymères réactifs possédant de faibles polydispersités et des masses molaires prédictibles. Les précurseurs ainsi définis sont facilement convertis, en polycations par exemple. Ils sont tout aussi facilement fonctionnalisés par des fluorophores dérivés de la coumarine ou du pérylène. Les fluorophores en tant que chaînes pendantes servent de marqueurs pour étudier le processus de dépôts alternés, alors que l'influence des variations au niveau moléculaire peut être systématisée. De plus, en utilisant des fluorophores complémentaires, il devient possible de mener des études sur le transfert de fluorescence (FRET) au sein de milieux organisés. Les cycles de dépôts alternés ont été suivis par spectroscopie UV-Vis, éllipsométrie et reflexion des rayons X. Une croissance régulière est observée dans le cas des trois polycations marqués. Il convient de noter que les études UV-Vis et de fluorescence révèlent la formation de larges aggrégats de fluorophores au sein des multicouches, dans le cas d'une coumarine et du dérivé de pérylène. Lorsque les polycations complémentaires sont utilisés dans des films minces mixtes, le FRET est observé. La nature radiative ou non-radiative du processus de transfert d'énergie a été confirmée par des mesures de déclin de fluorescence. Layer-by-Layer (LbL) assembly Controlled free radical polymerization
157	Laser flash photolysis studies of halogen atom reactions of atmospheric interest Laine, Patrick L. 24 October 2011 (has links) The Earth's atmosphere is a large photochemical reactor consisting primarily of N2 (~78%) and O2 (~21%) with Ar and water vapor being the next most abundant constituents. All of the remaining gases in the atmosphere are referred to as 'trace gases', and they play a critical role in understanding climate change, urban air quality, ozone production and depletion, and in determining the overall 'health' of the atmosphere. These trace components are present in our atmosphere with mixing ratios, i.e., mole fractions, ranging from sub parts per trillion to several hundred parts per million. One class of trace constituents that play a critical role in atmospheric chemistry are free radicals. Free radicals are highly reactive, often initiating the oxidation of natural and anthropogenic atmospheric species, thereby often controlling the fate and lifetimes of these species. The research comprising this dissertation focuses on laboratory studies of the kinetics and mechanisms of free radical (atomic halogen) reactions that can impact the levels of important trace atmospheric species. In the studies reported herein, laser flash photolysis (LFP) was coupled with time resolved atomic resonance fluorescence (RF) spectroscopic detection of Cl or Br atoms to investigate halogen atom chemistry. The research addresses three groups of reactions: Cl atom reactions with alkyl bromides, Cl and Br-initiated oxidations of small (C2-C6) alkenes, and Cl reactions with CH3SCH3 (DMS, dimethylsulfide) and CH3SeCH3 (DMSe, dimethylselenide). The alkyl bromide reactions were experimentally unique in that we were able to deduce kinetics of the Cl atom reaction with bromoethane, n-bromopropane, and 1,2-dibromoethane by monitoring the appearance of the Br product by LFP-RF. The Br is formed via elimination that occurs essentially instantaneously following β-H abstraction by the Cl atom. All three of the bromoalkanes investigated are emitted into the atmosphere primarily from anthropogenic sources and all three have been identified by the World Meteorological Organization (WMO) as very short-lived (lifetime less than 6 months) source gases with significant ozone depletion potentials (ODPs). Additionally, the bromoalkanes mentioned above have been of interest as model compounds for larger partially halogenated organics found in the atmosphere, and they have been considered as potential replacement compounds for chlorofluorocarbons (CFCs) that have been banned as a result of the Montreal Protocol. Brominated very short-lived compounds are thought to contribute 20-25% of total stratospheric bromine. Thus, there is considerable interest in understanding the atmospheric chemistry of even the most short-lived organic bromine compounds. Temporal profiles of Br atoms provided important kinetic and mechanistic insight for the reactions over a wide range of temperature and pressure. Temperature-dependent rate coefficients are determined for the alkyl bromides of interest for the first time, and the potential importance of the Cl reaction as an atmospheric degradation pathway for each alkyl bromide is qualitatively assessed. The studies of halogen atom reactions with alkenes focused on formation of weakly-bound adducts where kinetics of adduct formation and dissociation as well as non-adduct forming channels were evaluated. The elementary steps in the Br initiated oxidation of the alkenes 2-methyl-1,3-butadiene (isoprene), 2,3-dimethyl-2-butene (tetramethylethylene, TME), and 1,3-butadiene have been investigated. The experimental kinetic database for these reactions is quite sparse. The kinetic results reported herein, suggests that Br reaction with the above olefins is much faster than previously thought. Analysis of the temperature dependence of the "approach to equilibrium" kinetic data in conjunction with electronic structure calculations allows for determination of enthalpy and entropy changes associated with each addition reaction. Where possible, both forward addition and reverse dissociation channels as well as H-abstraction pathways were characterized. The enthalpy change associated with the addition reaction to give the Br−isoprene and Br−1,3-butadiene adducts has been determined for the first time and the bond dissociation enthalpy obtained for the Br−TME adduct is in reasonable agreement with the only other previously reported value. It should be noted that in the case of isoprene and 1,3-butadiene, there are multiple possible adducts that could be formed. In order to help clarify which adducts are more or less likely to be formed, we rely on electronic structure calculations (see Chapter 5) to aid in our overall understanding of the adduct forming channels. Furthermore, for the Br reactions with the three alkenes above, atomic Br kinetics have been monitored directly both in the absence and in the presence of O2 which allowed, for the first time, determination of rate coefficients for the elementary steps in the overall complex mechanism including determination of the Br−olefin + O2 rate coefficient. Also included in this group of reactions is the chlorine reaction with isoprene. In addition to the well-known fact that isoprene is emitted into the atmosphere from vegetation, a potentially significant marine source of isoprene has received considerable attention. Chlorine has long been thought to exist primarily in marine environments, however, recent findings also suggest a significant Cl production rate in the middle of the continental United States. There are numerous room temperature kinetic studies for the Cl + isoprene reaction in the literature, however, there is only one temperature dependent study reported. Current recommended 298 K rate coefficients for isoprene reactions suggest the Cl reaction is ~ 4x faster than the analogous OH reaction. If indeed this is the case, the Cl reaction could play a non-neglibible role in isoprene oxidation in atmospheric locales where Cl concentrations are relatively high. In addition, the C−Cl bond strength in Cl−C5H8 is obtained from direct measurements of the forward and reversible addition rate coefficients. Our results are compared with the literature data, and the potential importance of Cl-initiated oxidation as an atmospheric sink for isoprene is assessed. The final group of reactions investigated involves reactions of Cl with DMS and DMSe. DMS and DMSe are the most prevalent sulfur and selenium compounds emitted to the atmosphere from the oceans. The oxidation of DMS has been studied extensively due to the interest in the possible role of DMS oxidation in the formation of sulfate aerosols, however, DMSe oxidation processes have hardly been studied at all. And, DMSe oxidation products are likely to be less volatile than the analogous DMS species. Selenium is an essential nutrient for many plants and animals; however, there is a fine line between enough and excess selenium which can be toxic. Most studies suggest that atmospheric deposition is an important source of Se contamination, and it is therefore critical to evaluate the source emissions and fate of Se in the atmosphere. Since the majority of atmospheric Se exists in the form of DMSe, determination of the kinetics and oxidation mechanisms of DMSe will go a long way towards understanding the global biogeochemical cycle of Se. Both reversible addition and H-abstraction pathways have been characterized, and the first experimental determination of bond strength of the gas-phase DMS−Cl and DMSe−Cl adducts have been obtained. Bromine atom reactions Chlorine atom reactions Halogen atoms Gas phase reactions Free radical reactions Free radicals (Chemistry) Chemical reactions Thermochemistry Atmosphere Atmosphere Laser observations
158	Funktionalisierung von Silikonoberflächen Roth, Jan 10 February 2009 (has links) (PDF) Poly(dimethylsiloxan) (PDMS) ist ein wichtiges Polymer, das zunehmend in der Mikroelektronik aufgrund seiner hervorragenden Elastizität und thermischen Stabilität Verwendung findet. Ein limitierender Faktor für den Einsatz von PDMS ist aufgrund des Fehlens von reaktiven Gruppen und der niedrigen freien Oberflächenenergie seine geringe Adhäsion zu anderen Materialien. Zur Erhöhung der Adhäsion ist deshalb die Einführung von polaren, funktionellen Gruppen notwendig. Hier lag die Motivation der vorliegenden Arbeit, die sich eine gezielte Funktionalisierung von PDMS-Oberflächen als Aufgabe gesetzt hatte. Im ersten Teil der Arbeit wurde eine Verbesserung der Adhäsion zu einem fotostrukturierbaren Epoxidharz mittels der Sauerstoff- und Ammoniakplasmabehandlung angestrebt. In beiden Fällen führte die Plasmabehandlung zu der Einführung von unterschiedlichsten funktionellen Gruppen auf die Oberfläche und zu einer Verbesserung des Benetzungsverhaltens gegenüber Wasser. Zudem wurden Haftfestigkeiten erzielt, die um ein Vielfaches höher waren als jene zwischen Epoxidharz und einer unbehandelten PDMS-Oberfläche. Jedoch waren die hydrophilen Eigenschaften nach der Plasmabehandlung während der Lagerung an Luft zeitlich begrenzt, die PDMS-Oberfläche kehrt innerhalb kurzer Zeit in den einst hydrophoben Ausgangszustand zurück. Der Alterungsvorgang wird als „Hydrophobic Recovery“ bezeichnet und ist bei PDMS-Oberflächen, die höheren Plasmaleistungen und Behandlungszeiten ausgesetzt wurden, besonders auffällig. Die Vermeidung dieser Problematik war der Ausgangspunkt für den zweiten Teil der Arbeit. Auf der Grundlage der über die Plasmabehandlungen erzeugten funktionellen Gruppen wurden neue Konzepte für eine kovalente Anbindung von verschiedenen funktionellen Homo- und Copolymeren über die „Grafting to“-Technik entwickelt. Neben der Erhöhung der Adhäsion zu dem Epoxidharz war es möglich, das Benetzungsverhalten gegenüber Wasser durch die Unterbindung der „Hydrophobic Recovery“ zu stabilisieren. Des Weiteren gelang es, durch die Wahl der funktionellen Polymere, die PDMS-Oberfläche gezielt mit gewünschten Eigenschaften auszustatten. Somit ist der Einsatz der polymermodifizierten Oberflächen, außer in der Mikroelektronik, auch auf andere Anwendungen, wie der Biomedizin, der Mikrofluidik oder der Softlithografie übertragbar, in denen eine beständige, definierte Oberflächenfunktionalisierung ein wichtiges Kriterium darstellt. Poly(dimethylsiloxan) Niederdruckplasmabehandlung Adhäsion freie radikalische Polymerisation Grafting poly(dimethyl siloxane) low pressure plasma treatment adhesion free radical polymerization grafting ddc:540 rvk:VK 8007
159	Synthesis and Characterization of Ethylene-Acrylic Acid Copolymers Produced under High Pressure Nergui, Undrakh 08 July 2009 (has links) No description available. 660 Technische Chemie Mathematics and Computer Science Nicht-statistische Copolymere Copolymeren ethene Acrylsäure acrylic acid copolymerization random copolymers free radical polymerization 35.80 Makromolekulare Chemie SW
160	The synthesis and application of novel profluorescent nitroxides as probes for polymer degradation Blinco, James Peter January 2008 (has links) This PhD project has expanded the knowledge in the area of profluorescent nitroxides with regard to the synthesis and characterisations of novel profluorescent nitroxide probes as well as physical characterisation of the probe molecules in various polymer/physical environments. The synthesis of the first example of an azaphenalene-based fused aromatic nitroxide TMAO, [1,1,3,3-tetramethyl-2,3-dihydro-2-azaphenalen-2-yloxyl, was described. This novel nitroxide possesses some of the structural rigidity of the isoindoline class of nitroxides, as well as some properties akin to TEMPO nitroxides. Additionally, the integral aromatic ring imparts fluorescence that is switched on by radical scavenging reactions of the nitroxide, which makes it a sensitive probe for polymer degradation. In addition to the parent TMAO, 5 other azaphenalene derivatives were successfully synthesised. This new class of nitroxide was expected to have interesting redox properties when the structure was investigated by high-level ab initio molecular orbitals theory. This was expected to have implications with biological relevance as the calculated redox potentials for the azaphenalene ring class would make them potent antioxidant compounds. The redox potentials of 25 cyclic nitroxides from four different structural classes (pyrroline, piperidine, isoindoline and azaphenalene) were determined by cyclic voltammetry in acetonitrile. It was shown that potentials related to the one electron processes of the nitroxide were influenced by the type of ring system, ring substituents or groups surrounding the moiety. Favourable comparisons were found between theoretical and experimental potentials for pyrroline, piperidine and isoindoline ring classes. Substitution of these ring classes, were correctly calculated to have a small yet predictable effect on the potentials. The redox potentials of the azaphenalene ring class were underestimated by the calculations in all cases by at least a factor of two. This is believed to be due to another process influencing the redox potentials of the azaphenalene ring class which is not taken into account by the theoretical model. It was also possible to demonstrate the use of both azaphenalene and isoindoline nitroxides as additives for monitoring radical mediated damage that occurs in polypropylene as well as in more commercially relevant polyester resins. Polymer sample doped with nitroxide were exposed to both thermo-and photo-oxidative conditions with all nitroxides showing a protective effect. It was found that isoindoline nitroxides were able to indicate radical formation in polypropylene aged at elevated temperatures via fluorescence build-up. The azaphenalene nitroxide TMAO showed no such build-up of fluorescence. This was believed to be due to the more labile bond between the nitroxide and macromolecule and the protection may occur through a classical Denisov cycle, as is expected for commercially available HAS units. Finally, A new profluorescent dinitroxide, BTMIOA (9,10-bis(1,1,3,3- tetramethylisoindolin-2-yloxyl-5-yl)anthracene), was synthesised and shown to be a powerful probe for detecting changes during the initial stages of thermo-oxidative degradation of polypropylene. This probe, which contains a 9,10-diphenylanthracene core linked to two nitroxides, possesses strongly suppressed fluorescence due to quenching by the two nitroxide groups. This molecule also showed the greatest protective effect on thermo-oxidativly aged polypropylene. Most importantly, BTMIOA was found to be a valuable tool for imaging and mapping free-radical generation in polypropylene using fluorescence microscopy.

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