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Synthesis and Characterization of Block and Graft Syndiotactic Polystyrene Copolymer.zhuo, yi-hong 10 July 2002 (has links)
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Preparation of the Syndiotactic Polystyrene Copolymer by Chemical ModificationsChen, Yu-Pin 03 June 2003 (has links)
The main object of this study is to explore the possibility of using metallocene catalyst and reagent toe preparation syndiotactic polystyrene (sPS) framework connected with different polymer segments. Despite its enhanced thermal stability, the stereo-regular sPS generally has poor miscibility with other conventional polymers, which substantially limits its use in commerce. Therefore, chemical modifications on sPS were attempted in this study to hopefully introduce polar chain segments into the olefinic sPS chains and to possibly vary its properties and so, its miscibility with other polymers.
Here, a novel metallocene catalyst prepared from (
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Exploring Selectivity and Hysteresis : Kinetic Studies on a Potato Epoxide HydrolaseLindberg, Diana January 2010 (has links)
The kinetic mechanism of an α/β hydrolase fold epoxide hydrolase from potato, StEH1, has been studied with the aims of explaining the underlying causes for enantio- and regioselectivity, both being important for product purity. Further effort has been laid upon understanding the causes of a hysteretic behavior discovered in the measurements leading to Paper I. The enantioselectivity was investigated with substrates differing only in substituent size at one carbon of the oxirane ring structure. In catalysis with trans-stilbene oxide and styrene oxide, enantioselectivity is the result of differences in alkylation rates. In pre-steady state measurement with trans-2-methylstyrene oxide (2-MeSO), a rate-limiting step involving slow transitions, referred to as hysteresis, was discovered. With this substrate enantioselectivity is proposed to be a consequence of the catalytic rate of (1R,2R)-enantiomer being more influenced by the hysteretic behavior than was the rate of the other enantiomer. In steady-state measurements with (1R,2R)-2-MeSO, at different temperatures and pH, hysteretic cooperativity was displayed. It can be concluded that this behavior is dependent on the relationship between kcat and the rate of transition between two Michaelis complexes. From the differences in pH dependence of kcat/KM in formation of the two diols resulting from low regioselectivity in catalysis of (1R,2R)-2-MeSO, it is suggested that hysteresis is a result of the substrates placed in different conformational modes within the active site cavity. Regioselectivity is proposed to be the result of specific interactions between the catalytically important Tyr and the substrate, with a link between KM-values and degree of regioselectivity. Furthermore, the hysteretic kinetic model proposed can explain hysteresis, cooperativity and regioselectivity resulting from StEH1 catalyzed hydrolysis of (1R,2R)-2-MeSO.
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Structure des solutions aqueuses de polyélectrolytes fortement chargés / Structure of aqueous solutions of strongly charged polyelectrolytesLorchat, Philippe 06 September 2012 (has links)
Nous étudions la structure des solutions concentrées de polyélectrolytes (PE). Celle-ci n’a fait l’objet que de rares études expérimentales et aucun ordre d'orientation n'a jamais pu être observé dans les solutions de PE flexibles et semi-flexibles, bien que des travaux théoriques, basés sur l’approche d’Onsager, prévoient l'apparition d'une phase nématique aux fortes concentrations. Nous avons mesuré la position q* dans l'espace réciproque du pic présent dans la fonction de corrélation des solutions de PE fortement chargés obtenue par diffusion de rayonnement (DXPA et DNPA), et avons confronté sa variation avec la concentration c aux lois d'échelles théoriques q*~ca. Nous avons combiné des très fortes concentrations avec une haute résolution spatiale. La rigidité intrinsèque du PE est le paramètre clef de l’étude. En effet, le PSS, PE flexible, présente 3 régimes déjà connus : a=1/2 -régime semi-dilué- a=1/4 -régime concentré- un régime « ionomère » aux plus fortes concentrations pour lequel a=0. Le PDADMAC, PE semi-flexible, présente un comportement plus original puisque 4 régimes se succèdent : régimes semi-dilué et concentré avec a=1/2 et 1/4, puis deux régimes pour lesquels a=1 puis 1/2 qui sont totalement inédits. Le PaMSS, de rigidité intrinsèque intermédiaire, présente un comportement ambivalent, puisque les régimes semi-dilué et concentré précèdent un régime où a=1, puis un comportement « ionomère ». Nous introduisons un modèle simple permettant d'interpréter la succession des régimes a=1 puis 1/2 par l'apparition d'un ordre d'orientation. Nous discutons aussi les différences observées par DXPA et DNPA, et le rôle de la force ionique, variée par ajout de sel. / The structure of concentrated polyelectrolyte (PE) solutions is studied. There is a lack of experimental data on these systems. Specifically, no orientational order has ever been observed in solutions of flexible or semi-flexible PE, even though the existence of a nematic phase has been theoretically predicted at high concentration. We have measured the position q* in the reciprocal space of the peak that is present in the correlation function of aqueous solutions of highly charged PE, obtained by scattering measurements (SAXS and SANS). We combined high spatial resolution and a very wide concentration range to compare the variation of q* versus the concentration c, with the predicted scaling laws q*~ca. The intrinsic stiffness of PE is the key parameter of our study. Indeed, PSS, a flexible PE, exhibits 3 regimes already described: a=1/2 -semi-dilute regime- a=1/4 -concentrated regime- an “ionomeric” regime at extreme concentrations, for which a=0. PDADMAC is semi-flexible and exhibits a unique series of exponents involving 4 regimes: semi-dilute and concentrated regimes with a=1/2 and 1/4, followed by 2 regimes associated with a=1 and 1/2 respectively, which are new and unpredicted for PE solutions. PaMSS has an intermediate intrinsic stiffness, and exhibits hybrid behaviour. The semi-dilute and concentrated regimes are followed by an a=1 regime, and then an “ionomeric” regime for extreme concentrations. We introduce a simple model which explains the succession of the a=1 and 1/2 regimes as the appearance of an orientational order. We also discuss the differences between SAXS and SANS measurements, and the role played by the ionic strength, when salt is added.
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Methyl Internal Rotation Probed by Rotational SpectroscopyGurusinghe, Ranil Malaka 02 November 2016 (has links)
No description available.
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