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Development of New N-Cyclopropyl Based Electron Transfer Probes for Cytochrome P-450 and Monoamine Oxidase Catalyzed ReactionsGrimm, Michelle L. 26 May 2011 (has links)
The recent upsurge of degenerative diseases believed to be the result of oxidative stress has sparked an increased interest in utilizing the fundamental principles of physical organic chemistry to understand biological problems. Enzyme pathways can pose several experimental complications due to their complexity, therefore the small molecule probe approach can be utilized in an attempt understand the more complex enzyme mechanisms. The work described in this dissertation focuses on the use of N-cyclopropyl amines that have been used as probes to study the mechanism of monoamine oxidase (MAO) and cytochrome P-450 (cP-450).
A photochemical model study of benzophenone triplet (3BP) with the MAO-B substrate 1-methyl-4-phenyl-1,2,3,6-tetrahydropyridine (MPTP) and two of its derivatives, 1-cyclopropyl-4-phenyl-1,2,3,6-tetrahydropyridine and (+/-)-[trans-2-phenylcyclopropyl-4-phenyl-1,2,3,6-tetrahydropyridine is presented in Chapter 2. The barrier for ring opening of aminyl radical cations derived from N-cyclopropyl derivatives of tertiary amines (such as MPTP) is expected to be low. Reactions of 3BP with all three compounds are very similar. The results suggest that the reaction between benzophenone triplet and tertiary aliphatic amines proceed via a simple hydrogen atom transfer reaction. Additionally these model examinations provide evidence that oxidations of N-cyclopropyl derivatives of MPTP catalyzed by MAO-B may not be consistent with a pure SET pathway.
The chemistry of N-cyclopropyl amines has been used to study the mechanism of amine oxidations by cP-450. Until recently, the rate constant for these ring opening reactions has not been reported. Direct electrochemical examinations of N-cyclopropyl-N-methylaniline showed that the radical cation undergoes a unimolecular rearrangement consistent with a cyclopropyl ring opening reaction. Examination of both the direct and indirect electrochemical data showed that the oxidation potential N-cyclopropyl-N-methylaniline to be +0.528 V (0.1 M Ag⁺/Ag), and rate constant for ring opening of 4.1 x 10⁴ s⁻¹. These results are best explained by two phenomena: (i) a resonance effect in which the spin and charge of the radical cation in the ring closed form is delocalized into the benzene ring hindering the overall rate of the ring opening reaction, and/or (ii) the lowest energy conformation of the molecule does not meet the stereoelectronic requirements for a ring opening pathway. Therefore a new series of spiro cyclopropanes were designed to lock the cyclopropyl group into the appropriate bisected conformation. The electrochemical results reported herein show that the rate constant for ring opening of 1'-methyl-3',4'-dihydro-1'H-spiro[cyclopropane-1,2'-quinoline] and 6'-chloro-1'-methyl-3',4'-dihydro-1'H-spiro[cyclopropane-1,2'-quinoline] are 3.5 x 10² s⁻¹ and 4.1 x 10² s⁻¹ with redox potentials of 0.3 V and 0.366 V respectively. In order to examine a potential resonance effect a derivative of N-methyl-N-cyclopropylaniline was synthesized to provide a driving force for the ring opening reaction thereby accelerating the overall rate of the ring opening pathway. The electrochemical results show that the rate constant for ring opening of 4-chloro-N-methyl-N-(2-phenylcyclopropyl)aniline to be 1.7 x 10⁸ s⁻¹ . The formal oxidation potential (E°OX) of this substrate was determined to be 0.53 V.
The lowered redox potentials of 1'-methyl-3',4'-dihydro-1'H-spiro[cyclopropane-1,2'-quinoline] and 6'-chloro-1'-methyl-3',4'-dihydro-1'H-spiro[cyclopropane-1,2'-quinoline] can be directly attributed to the electron donating character of the ortho alkyl group of the quinoline base structure of these spiro derivatives, and therefore the relative energy of the ring closed radical cations directly affects the rate of ring opening reactions. The relief of ring strain coupled with the formation of the highly resonance stabilized benzylic radical explains the rate increase for the ring opening reaction of 4-chloro-N-methyl-N-(2-phenylcyclopropyl)aniline. / Ph. D.
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Development of Controlled Ring-Opening Polymerization of O-CarboxyanhydridesZhong, Yongliang 27 October 2020 (has links)
The aim of my Ph.D. thesis is to summarize my research on the development of ring-opening polymerization (ROP) of O-carboxyanhydrides (OCAs) to synthesize functionalized, degradable polyesters. Biodegradable polyesters are promising alternatives to conventional petroleum-based non-degradable polyolefins and they are widely used in everyday applications ranging from clothing and packaging to agriculture and biomedicine. Commercially available polyesters, such as poly(lactic-co-glycolic acid), poly(lactic acid), and polycaprolactone, hydrolyze in physicochemical media. They have been approved by FDA and widely used for medical applications. However, the lack of side-chain functionality in polyesters and in corresponding monomers greatly plagues their utility for applications that demand physicochemical properties such as high stiffness, tensile strength and elasticity. Increasing efforts have been devoted to the introduction of pendant groups along the polymer chain in order to modify and modulate the physicochemical properties of polyesters and thereby to expand their applications.
Over the last decade, OCAs have emerged as an alternative class of highly active monomers for polyester polymerization. OCAs are prepared from amino acids and thus have a richer range of side chain functionalities than lactone or lactide. Like lactones, OCAs can undergo ROP to obtain polyesters. Unfortunately, current ROP methods, especially those involving organocatalysts, result in uncontrolled polymerization including epimerization for OCAs bearing electron-withdrawing groups, unpredictable molecular weights (MWs), or slow polymerization kinetics. Based on our recent success of Ni/Ir photoredox catalysis allowing for rapid synthesis of high-MWs polyesters, we further explore new polymerization chemistry to use earth-abundant metal complexes to replace expensive rare-earth metal photocatalysts, and practice the polymerization in moderate and energy-efficient reaction conditions.
This thesis introduces novel photoredox and electrochemical earth-abundant metal catalysts that overcome above difficulties in the ROP chemistry of OCAs, and allow for the preparation of stereoregular polyesters bearing abundant side-chain functionalities in a highly controlled manner. Specifically, various highly active metal complexes have been developed for stereoselective ROP of OCAs, either using light or electricity, to synthesize syndiotactic or stereoblock copolymers with different thermal properties. Additionally, simple purification protocols of OCAs have also been initially studied, which potentially paves the way to bulk production of functional monomers.
In this thesis, I first describe newly-developed photoredox Co/Zn catalysts to achieve a controlled ROP of enantiopure OCAs under mild reaction conditions (Chapter 2). Such discovery is extended to the combination use of Co catalysts with various Zn/Hf complexes that enable stereoselective controlled ROP of racemic OCAs for the preparation of stereoregular polyesters (Chapter 3). The mechanistic studies of the aforementioned developments lead to the application of such a catalytic system in controlled electrochemical ROP of OCAs (Chapter 4). Such chemistry can also be translated to stereoselectively electrochemical ROP of racemic OCAs to either syndiotactic or stereoblock polyesters, allowing precise control of polyester's tacticity and sequence (Chapter 5). An overview future work has been summarized (Chapter 6). / Doctor of Philosophy / Polyesters are widely used in everyday applications ranging from clothing and packaging to agriculture and biomedicine. Different from conventional unrecyclable plastics, polyesters are usually biocompatible and biodegradable, and can be synthesized from renewable resources. A few commercially available polyesters have been approved by FDA and widely used for medical applications. However, their utility for applications that demand various mechanical and chemical properties is greatly limited by the lack of side-chain functional groups in polyesters and in their monomers—lactones. Increasing efforts have been devoted to the introduction of pendant groups along the polymer chain in order to modify and modulate the desired properties of polyesters and thereby to expand their applications.
Over the last decade, O-carboxyanhydrides (OCAs) have emerged as an alternative class of highly active monomers for polyester polymerization. OCAs can be prepared from renewable source amino acids and thus have a richer range of side chain functional groups. Like lactones, OCAs can undergo ring-opening polymerization (ROP). Unfortunately, current ROP methods usually result in uncontrolled polymerization of OCAs including loss of stereoregularity, unpredictable molecular weights, or slow polymerization rate.
To address the above-described polymer chemistry and materials challenges, I have been motivated to develop a new polymer chemistry knowledge base when starting my Ph.D. program. I was first involved in the development of a controlled photoredox polymerization of OCAs produces polyesters with various side chain functional groups. By using photoredox Ni/Zn/Ir catalysts, stereoregular high molecular weight polyesters can be synthesized from racemic OCAs in a rapid, controlled manner. However, this catalytic system has to be used at -20 °C despite so successful in preparing stereoblock polyesters.
Encouraged by our recent success in this area, I started to work on the discovery of other transition metal complexes such as the Co complexes used in N-carboxyanhydride polymerization. Ultimately, innovative photoredox Co/Zn catalysts has been successfully developed, and applied to our protocol to achieve the controlled ROP of enantiopure OCAs under mild reaction condition (Chapter 2). The Co catalyst can replace both Ni and Ir in aforementioned photoredox system. Meanwhile, the combination of Co catalysts and various Zn/Hf complexes has also been developed to undergo photoredox ROP of racemic OCAs to efficiently produce polyesters with different microstructures (Chapter 3).
Although photoredox ROP is an efficient method for synthesizing degradable polyesters, great decrease in photonic flux with the depth of the reaction medium makes it less energy efficient compared to electricity. Therefore, we then extended our protocol to electrochemical reaction, which is one of the most energy-efficient chemical reactions. The newly identified Co/Zn catalytic system can be activated by electric current to mediate rapid electrochemical ROP (eROP) of enantiopure OCAs, allowing for the synthesis of isotactic polyesters in a highly controlled manner (Chapter 4). Additionally, stereoselective eROP of racemic OCAs has been firstly achieved by using various combinations of Co and Zn/Hf complexes (Chapter 5).
In summary, my research produces unique and transformative insights into the innovative photoredox and electrochemical ROP mediated by metal catalysts. Given the importance and versatility of biodegradable and biocompatible polyester materials, the chemistry invented by our team can be expected to serve as a new platform for various applications in material and biomedical engineering.
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Designing immobilized catalysts for chemical transformations: new platforms to tune the accessibility of active sitesLong, Wei 03 July 2012 (has links)
Chemical catalysts are divided into two traditional categories: homogeneous and heterogeneous catalysts. Although homogeneous (molecular) catalysts tend to have high activity and selectivity, their wide application is hampered by the difficulties in catalyst separation. In contrast, the vast majority of industrial scale catalysts are heterogeneous catalysts based on solid materials. Immobilized catalysts, combining the advantages of homogeneous and heterogeneous catalysts, have developed into an important field in catalysis research. This dissertation presents synthesis, characterization and evaluation of several novel immobilized catalysts. In the first part, MNP supported aluminum isoproxide was developed for ROP of Є-caprolactone to achieve facile magnetic separation of catalysts from polymerization system and reduce toxic metal residues in the poly(caprolactone) product. Chapter 3 presents a silica coated MNP supported DMAP catalyst that was synthesized and displayed good activity and regio-selectivity in epoxide ring opening reactions. In Chapter 4, hybrid sulfonic acid catalysts based on polymer brush materials have been developed. The unique polymer brush architecture permits high catalyst loadings as well as easy accessibility of the active sites to be achieved in this catalytic system. In Chapter 5, aminopolymer-silica composite supported Pd catalysts with good activity and selectivity were developed for the selective hydrogenation of alkynes. In this case, the aminopolymer composite works as a stabilizer for palladium nanoparticles, as well as a modifier to tune the catalyst selectivity. All in all, the general theme of the thesis is developing new immobilized catalysts with improved activity/selectivity as well as easy separation via rational catalyst design.
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Elaboration de copolymères greffés à squelette poly(1,4-butadiène) et à greffons polaires par combinaison ROMP/ROP / Synthesis of graft copolymers with 1,4-polybutadiene backbone and polar grafts by combination of ROP and ROMPLeroux, Flavien 07 October 2014 (has links)
Le sujet de cette thèse concerne l’élaboration de copolymères greffés possédant un squelette poly(1,4-butadiène) et une haute densité de greffons polaires. La synthèse de copolymères à squelette strictement poly(1,4-butadiène) et possédant une haute densité de greffons selon un enchaînement strictement tête-à-tête a été réalisée par polymérisation par ouverture de cycle par métathèse (ROMP) de monomères cyclobutène 3,4-disubstitués. Le choix des greffons polaires s’est porté sur des poly(Ɛ-caprolactone)s (PCL) et des poly(L-lactide)s (PLLA) obtenus par polymérisation par ouverture de cycle (ROP). Ces polyesters aliphatiques qui présentent une biocompatibilité élevée et une (bio)dégradation rapide, sont utilisés dans de nombreuses applications biomédicales. De plus, les copolymères greffés à greffons polyester peuvent donner accès à des nanomatériaux poreux suite à leur organisation en solution ou à l’état solide, suivie de l’hydrolyse des chaînes polyester.Les copolymères greffés poly(1,4-butadiène)-g-polyester ont été synthétisés selon les stratégies grafting through et grafting from, à partir d’inimers (initiator-monomer) cyclobutène portant une ou deux fonctionalités alcool, capable d’amorcer la ROP du L-lactide ou de l’ Ɛ-caprolactone. La stratégie grafting through a, dans un premier temps, été étudiée. Des macromonomères polyester de type PCL ou PLLA ont été synthétisés. La ROMP de ces macromonomères a conduit à des copolymères greffés poly(1,4-butadiène)-g-polyesters en forme d’étoile de structure définie et dont la densité des greffons est parfaitement contrôlée. La stratégie grafting from a, quant-à-elle, permis d’accéder à des copolymères greffés en forme de peigne. L’organisation des architectures macromoléculaires obtenues a été visualisée par microscopie à force atomique (AFM) et microscopie électronique à transmission (TEM). / The objective of this work was the preparation of graft copolymers with a poly(1,4-butadiene) backbone and a high density of polar grafts. We used a consecutive Ring-Opening Metathesis Polymerization (ROMP)/Ring-Opening Polymerization (ROP) route to prepare poly(1,4-butadiene)-g-polyesters from cyclobutenyl macromonomers bearing one or two polyester segment(s) derived from L-lactide (L-LA) or Ɛ-caprolactone (Ɛ-CL). Poly(L-lactide)s (PLLA) or poly(Ɛ-caprolactone)s (PCL) are important polymers as they are easily (bio)degradable and have tremendous applications as engineering plastics and within the biomedical field. An attractive feature of polyester-grafted copolymers is their potential to act as building blocks for nanomaterials synthesis thanks to the hydrolytically degradable polyester grafts. Cyclobutenyl polyester macromonomers bearing one and two PCL or PLLA arms have been successfully prepared by organocatalyzed ROP of Ɛ-CL or L-LA from a cyclobutenyl alcohol acting as an initiator. Subsequent "grafting through" by ROMP using Grubbs’ second generation catalyst afforded poybutadiene brushes featuring pendant polyester (PLLA or PCL) side-chains. This efficient ROP/ROMP two-step approach has thus allowed the synthesis of well-defined poly(1,4-butadiene)-g-polyester copolymers. The synthesis of graft copolymers via the grafting from approach by ROMP and ROP was also studied. ROMP of 3,4-disubstituted cyclobutenes containing one and two initiating hydroxyl sites for ROP was first investigated with ruthenium initiators. The resulting well-defined poly(1,4-butadiene)s were then used as macroinitiators for the ROP of L-LA or Ɛ-CL. After the ROP, brush copolymers with high molecular weight have been obtained and characterized by microscopy.
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Synthèse de nanoconjugués PEG-PLA pour des applications biomédicales : libération contrôlée et Imagerie / Synthesis of nanoconjuguate PEG-PLA for biomedical applications : drug delivrery and ImagingGontard, Gwenaëlle 13 June 2016 (has links)
Ce travail de thèse s’inscrit dans le cadre d’une collaboration entre Sanofi à Vitry-sur-Seine et le Laboratoire Hétérochimie Fondamentale et Appliquée (LHFA) à Toulouse, et a pour but de développer de nouveaux nanovecteurs à base de conjugués polymériques biodégradables et biocompatibles capables d’encapsuler, de transporter et de libérer des agents thérapeutiques. Les travaux précédemment réalisés au laboratoire, ont montré que la libération de principes actifs hydrophobes, tels que le Cabazitaxel de la famille des taxanes, pouvait être contrôlée grâce à l’architecture de conjugués de nature PEG-PLA. Dans le premier chapitre, une étude a été menée afin d’améliorer la cinétique de libération du principe actif, en tirant profit de la différence de pH qui réside entre les tissus sains et les tissus cancéreux. Différents liens (reliant le principe actif au copolymère) ayant un comportement pH dépendant ont été étudiés, comme l’hydrazone, l’acétal et le β-thiopropionate. La liaison ester boronique, dynamique en fonction du pH, a aussi été étudiée dans le but de déstructurer la NP et permettre indirectement d’améliorer la libération du principe actif. La synthèse et l’évaluation des divers conjugués ont montré que la structure polymérique amphiphile des conjugués inhibait considérablement le comportement pH dépendant attendu. Dans le second chapitre, plusieurs technologies comme le ciblage, permettant de diriger la NP dans l’organisme, ou l’imagerie permettant de les visualiser, ont été étudiées. L’influence de la structure des conjugués de forme Y et L sur les propriétés de reconnaissance et d’imagerie a été analysée. La structure Y offre quelques avantages quant à la quantité de ligand requise pour obtenir un ciblage actif optimal ainsi qu’une meilleure visualisation, en comparaison des résultats obtenus avec les conjugués L. La méthode de co-nanoformulation a permis de faire varier la quantité de ligand ou de sonde d’imagerie au sein des NPs. Dans le troisième chapitre, la synthèse et l’efficacité de sels de (bi)pyridinium comme catalyseurs pour la ROP de l’ε-caprolactone sont présentées. Un phénomène de coopérativité avec des bipyridiniums, dications donneurs de deux liaisons hydrogènes (IHBD) a été mis en évidence pour l’activation de l’ε-caprolactone, avec des activités en ROP plus importante en comparaison des systèmes impliquant la participation d’une seule liaison H. Les meilleurs systèmes ont pu être évalués plus en détail et ont permis d’accéder à des polymères de masses définies allant jusqu’à 13 000 g/mol. / This PhD thesis is based on a joint between Sanofi in Vitry-sur-Seine and LHFA. This work consists in the development of new nanovectors based on biodegradable and biocompatible polymerics conjugate that enable to encapsulate, transport and deliver therapeutic agents. Previous works in the laboratory have shown that the release of hydrophobic drugs, such as Cabazitaxel, a taxane derivative, could be controlled by the architecture of the conjugated PEG-PLA. In the first chapter, a study was realized to improve the release kinetics of the drug, taking advantage of the difference of pH between healthy and cancerous tissue. Different linkers (linking the drug to the copolymer) having a pH dependent behavior have been studied, such as hydrazone, acetal and β-thiopropionate. The boronic ester bonding, dynamic function of pH, was also studied in order to destroy the NP and indirectly improve the release of drug. The synthesis and the evaluation of various conjugates have shown that the amphiphilic polymeric structure of the conjugates significantly inhibited the expected pH-dependent behavior. In the second chapter, several technologies such as targeting or imaging were studied. The influence of the Y and L-shape on the recognition and imaging properties was analyzed. The Y-shape offers advantages like the amount of ligand required for optimal active targeting and better visualization, in comparison with the results obtained with the L conjugates. The method of co-nanoformulation allowed to adjust the ligand amount or imaging probe within the NPs. In the third chapter, the synthesis and efficiency of (bi)pyridinium salts as catalysts for the ROP of ε-caprolactone are presented. A collaborative behavior with dication bipyridiniums is bearing two hydrogen bonds (IHBD) was demonstrated for the activation of the ε-caprolactone, with greater ROP activities compared to systems involving the participation of only one H bond. The best systems were evaluated in more details and allowed access to polymers with a molecular weight of up to 13 000 g / mol.
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Catalyse énantiosélective redox: génération et réactivité d'oxo-radicaux anions induits par des complexes chiraux du titaneCourmarcel, James 19 December 2003 (has links)
Ce travail aborde l'étude d'oxo radicaux anions générés par des complexes de titane à basse valence ainsi que le contrôle stéréochimique lors de la formation de liaisons carbone carbone.
La première partie de ce travail traite de la synthèse de complexes chiraux du titane à partir de ligands de type salénol. Ces complexes sont ensuite mis en application dans la réaction de pinacolisation d'aldéhydes aromatiques et dans le couplage réducteurs d'imines. La réaction de l'aldéhyde avec le complexe de titane forme un radical α-oxo anion qui se dimérise et conduit à un diol. Deux atomes de carbone asymétriques sont créés. Le contrôle de la stéréochimie de la réaction constitue une partie importante du travail. Différents paramètres de la réaction sont étudiés afin d'augmenter la réactivité, la diastéréosélectivité et l'énantiosélectivité. La réactivité et la diastéréosélectivité sont parfaitement maîtrisées (> 95 % dans chaque cas). La réaction a été optimisée sur un substrat modèle, le benzaldéhyde et une énantiosélectivité égale à 84 % a pu être obtenue.
Le système a ensuite été étendu au couplage réducteur d'imines pour former des diamines chirales.
La seconde partie du travail consiste en l'ouverture réductrice d'époxyde par des complexes du titane. Ceci permet de créer des β-oxo radicaux anions qui sont capturés par des oléfines par réactions inter- ou intramoléculaire. Deux atomes de carbone asymétriques sont là aussi créés et le but final est de contrôler la stéréochimie de la réaction. Des hydroxy-esters sont formés après le couplage et une cyclisation intramoléculaire permet dans certains cas de synthétiser des -lactones.
Dans un premier temps, il a fallu synthétiser les époxy-alcènes en plusieurs étapes. Le couplage n'a pour le moment été réalisé qu'à partir d'un complexe achiral.
Abstract
This work approaches the study of oxo radicals anions generated by low valent titanium complexes and their application in the asymmetric carbon carbon bond formation.
The first part of this work deals with the synthesis of some chiral titanium complexes from salenol type ligands. These complexes are then tested in the pinacolisation of aromatic aldehydes and in the reducing coupling of imines. The reaction of the aldehyde with the titanium complex forms an α-oxo radical anion which dimerize and leads to a diol. Two asymmetric atoms of carbon are then created. The control of the stereochemistry of the reaction is the main part of this work. Various parameters of the reaction are studied to increase the reactivity, the diastereoselectivity and the enantioselectivity. The reactivity and the diastereoselectivity are perfectly mastered (> 95 % in every case). The reaction was optimized on a model substrate, benzaldéhyde, and enantioselectivities up to 84 % were achieved.
The system was then extended to the reducing coupling of imines to form chiral diamines.
The second part of the work is centered on the reducing opening of epoxide by low valent titanium complexes. This allows to create β-oxo radical anions which are captured by olefines by inter-or intramolecular reactions. Two asymmetric centers are also created and the final goal was to control the stereochemistry of the reaction. Hydroxy-esters are formed after the coupling and an intramolecular cyclization allows in certain cases to synthesize -lactones.
It was first necessary to synthesize the starting epoxy-alkenes. At the present stage of the study, the coupling on the model epoxy-alkene was only tested with an achiral complex.
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Selective ring opening of naphthenes present in heavy gas oil derived from Athabasca bitumenKotikalapudi, Chandra Mouli 17 September 2009
Removal of polynuclear aromatics from diesel fuel has become a focus of intense
research due to the stringent environmental legislation associated with clean fuels. In this
work, selective ring opening of model compound decalin over the set of catalysts
comprising of 1) Ir-Pt supported on mesoporous Zr-MCM-41, large and medium pore
zeolites like HY and H-Beta and 2) Ni-Mo/carbide on HY, H-Beta, Al-SBA-15, ¥ã-
alumina and silica alumina were studied. All the catalysts were extensively characterized
by BET surface area measurement, CO-chemisorption, XRD, FTIR, TPR and TPD of
ammonia. Ring opening of decalin was studied on these catalysts in a trickle-bed reactor
in a temperature range of 200- 400 ¡ÆC, pressure range of 2-7 MPa and LHSV of 1 to 3 h-
1. 31.7 and 65.0 wt.% of RO yield and selectivity were observed on Ir-Pt/HY catalyst at
220 ¡ÆC, whereas 34.0 and 40.0 wt.% of ring opening yield and selectivity were observed
on Ni-Mo carbide/HY catalyst at 240 ¡ÆC. From the model compound studies, Ir-Pt/HY,
Ni-Mo carbide/HY and Ni-Mo carbide/H-Beta were selected for study of hydrotreated
light gas oil in a trickle bed reactor. Ni-Mo carbide/HY performed better over other
catalysts and increased the cetane index of hydrotreated light gas oil by 12 units at 325
¡ÆC. A first order kinetic model was fitted for the hydrotreated light gas oil study. 89, 111
and 42 KJ/gmol of activation energies was observed for dearomatization, aromatization
and naphthenes cracking steps, respectively. The thermodynamic equilibrium calculations
reveal that the selectivity of ring opening products of decalin can be maximized by
favoring the formation of unsaturated compounds at higher operating temperatures.
Energetics of dealkylation and ring opening reactions of naphthenes in gas phase and on
the surface of Br©ªnsted acid sites were calculated using quantum chemical simulations. In
iv
gas phase, ratio of Arrhenius activation energies for forward and reverse reactions of RO
and dealkylation reactions are 1.92 and 1.82 respectively. Deakylation on different level
clusters revealed that surface reaction is the rate controlling.
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Selective ring opening of naphthenes present in heavy gas oil derived from Athabasca bitumenKotikalapudi, Chandra Mouli 17 September 2009 (has links)
Removal of polynuclear aromatics from diesel fuel has become a focus of intense
research due to the stringent environmental legislation associated with clean fuels. In this
work, selective ring opening of model compound decalin over the set of catalysts
comprising of 1) Ir-Pt supported on mesoporous Zr-MCM-41, large and medium pore
zeolites like HY and H-Beta and 2) Ni-Mo/carbide on HY, H-Beta, Al-SBA-15, ¥ã-
alumina and silica alumina were studied. All the catalysts were extensively characterized
by BET surface area measurement, CO-chemisorption, XRD, FTIR, TPR and TPD of
ammonia. Ring opening of decalin was studied on these catalysts in a trickle-bed reactor
in a temperature range of 200- 400 ¡ÆC, pressure range of 2-7 MPa and LHSV of 1 to 3 h-
1. 31.7 and 65.0 wt.% of RO yield and selectivity were observed on Ir-Pt/HY catalyst at
220 ¡ÆC, whereas 34.0 and 40.0 wt.% of ring opening yield and selectivity were observed
on Ni-Mo carbide/HY catalyst at 240 ¡ÆC. From the model compound studies, Ir-Pt/HY,
Ni-Mo carbide/HY and Ni-Mo carbide/H-Beta were selected for study of hydrotreated
light gas oil in a trickle bed reactor. Ni-Mo carbide/HY performed better over other
catalysts and increased the cetane index of hydrotreated light gas oil by 12 units at 325
¡ÆC. A first order kinetic model was fitted for the hydrotreated light gas oil study. 89, 111
and 42 KJ/gmol of activation energies was observed for dearomatization, aromatization
and naphthenes cracking steps, respectively. The thermodynamic equilibrium calculations
reveal that the selectivity of ring opening products of decalin can be maximized by
favoring the formation of unsaturated compounds at higher operating temperatures.
Energetics of dealkylation and ring opening reactions of naphthenes in gas phase and on
the surface of Br©ªnsted acid sites were calculated using quantum chemical simulations. In
iv
gas phase, ratio of Arrhenius activation energies for forward and reverse reactions of RO
and dealkylation reactions are 1.92 and 1.82 respectively. Deakylation on different level
clusters revealed that surface reaction is the rate controlling.
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Aggregation induced emission enhancement in relation to the secondary structures of poly(£^-benzyl-L-glutamate) containing fluorescent tetraphenylthiophene moietyLi, Shu-ting 13 July 2012 (has links)
In this study, tetraphenylthiophenen (TP) with aggregation-induced emission enhancement (AIEE) property is served as terminal and central fluorophores of poly(£^-benzyl-L-glutamate) (PBLG)-based polymers of TP1PBLG and TP2PBLG, respectively, to probe for the relationship between the secondary structure (£\-helix) of polypeptides and the ALEE-operative fluorescence (FL). Intermolecular aggregation of the central TP unit in the di-substituted TP2PBLG is sterically blocked by the large £\-helical PBLG chains, which lead to the reduced AIEE-oriented FL. On the contrast, the terminal TP units in TP1PBLG can easily approach each other to form aggregates with strong FL. Factor (e.g. solvent annealing) controlling the fraction of £\-helix chain also varies the corresponding emission intensity. Conformational difference between TP1PBLG and TP2PBLG evaluated from the infrared and the X-ray (wide- and small-angle) diffraction spectra is also used to verify its influence on the AIEE-operative FL behavior.
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Mechanistic studies of the metal catalyzed formation of polycarbonates and their thermoplastic elastomersChoi, Wonsook 15 May 2009 (has links)
Studies concerning the formation of industrially useful polycarbonates are the
focus of this dissertation. Of particular importance is the biodegradable polymer,
poly(trimethylene carbonate) which has a wide range of medical applications. The
production of polycarbonates can be achieved by the ring-opening polymerization of
cyclic carbonate, or the copolymerization of carbon dioxide and oxiranes or oxetanes.
For the production of polycarbonates from these monomers, Schiff base metal
complexes have been designed, synthesized, and optimized as catalysts. Detailed kinetic
and mechanistic studies have been performed for the ring-opening polymerization of
cyclic carbonates, as well as the copolymerization of carbon dioxide and oxiranes or
oxetane. In addition, the copolymerization of cyclic carbonates and cyclic esters to
modify the mechanical and biodegradable properties of materials used for medical
devices has been studied using biocompatible metal complexes. In the process for ring-opening polymerizations of trimethylene carbonate or
lactides, Schiff base metal complexes (metal = Ca(II), Mg(II) and Zn(II)) have been
shown to be very effective catalysts to produce high molecular weight polymers with
narrow polydispersities. Kinetic studies demonstrated the polymerization reactions to
proceed via a mechanism first order in [monomer], [catalyst], and [cocatalyst] if an
external cocatalyst is applied, and to involve ring-opening by way of acyl-oxygen bond
cleavage. The activation parameters (ΔH≠, ΔS≠ and ΔG≠) were determined for ringopening
polymerization of trimethylene carbonate, ring-opening polymerization of
lactides, and copolymerization of trimethylene carbonate and lactide.
In the process for copolymerization of carbon dioxide and oxetane, metal salen
derivatives of Cr(III) and Al(III) along with cocatalyst such as n-Bu4NX or PPNX (PPN
= bis(triphenylphosphine)iminium, and X = Br, Cl and N3) have been shown to be
effective catalysts to provide poly(trimethylene carbonate) with only trace amount of
ether linkages. The formation of copolymer is proposed not to proceed via the
intermediacy of trimethylene carbonate, which was observed as a minor product of the
coupling reaction. To support this conclusion, ring-opening polymerization of
trimethylene carbonate has been performed and kinetic parameters have been compared
with those from the copolymerization of carbon dioxide and oxetane.
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