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241	Transition metal catalysed carbonylation reactions in organic synthesis. Ferreira, Alta Carina 09 May 2008 (has links) The objective of the research described in the first part of this thesis involves the application of carbon monoxide and transition metals in key steps of a synthetic route to lavendamycin, an antic cancer compound, and its analogues. Lavendamycin is a pentacyclic compound that possesses a quinoline-5,8-quinone AB ring linked to a b- carboline CED ring. The development of general routes to the synthetic equivalents of the lavendamycin AB quinoline system together with a linker atom, quinoline -2- carboxaldehydes, as well as to the lavendamycin DE indole ring system, namely tryptophan derivatives, was addressed. The Pictet-Spengler cyclisation approach towards lavendamycin involves the reaction between quinoline-2-carboxaldehyde and tryptophan methyl ester to furnish the pentacyclic precursor of the methyl ester of lavendamycin. This synthetic approach requires the availability of quinoline-2-carboxaldehydes, previously prepared by the oxidation of 2-methylquinolines with toxic selenium dioxide. A general strategy towards the synthesis of the AB ring moiety utilising a pre-formed ring system such as commercially available 8-hydroxyquinoline has been successfully developed. It involved the high pressure palladium catalysed formylation of 2-bromo or other suitable 2-substituted quinoline derivatives under syngas (1:1 CO:H2). The preparation of the required 2-substituted quinoline derivative involved the methylation of the 8-hydroxylgroup followed by N-oxidation and then a rearrangement step. In both the Pictet-Spengler and Bischler-Napieralski synthetic approaches to lavendamycin, the CDE ring moiety is introduced using tryptophan methyl ester as building block. The application of this approach to the synthesis of lavendamycin analogues with a substituted D-ring required the availability of substituted tryptophan methyl esters. A general strategy towards the tryptophan derivatives starting with a Wittig reaction between a suitable 2-nitrobenzaldehyde precursor and 1,3-dioxolan-2- yl-methyltriphenylphosphonium bromide, followed by a two-stage, one -pot rhodium catalysed hydroformylation/reduction reaction, has been successfully developed. This methodology yielded ten different possible tryptophan precursors in moderate to good yields. The second part of the research described in this thesis included the identification of factors effecting the rate and regioselectivity of palladium catalysed methoxycarbonylation of a-olefins. The results showed that fast reactions under polar conditions give mainly linear esters. However, reactions under less polar conditions are slower, yielding mainly branched esters. Detailed analysis of the results suggest the operation of a so-called “cationic” mechanism (involving cationic palladium intermediates) in the formation of mainly linear esters, but the operation of a so-called “neutral” mechanism (involving neutral palladium intermediates) in the formation of mainly branched esters. The nature of the phosphine ligands was found to play a significant, but secondary role in determining regioselectivity of methoxycarbonylation. Another objective was the optimisation of the palladium catalysed hydroformylation of a-olefins. An evaluation of the efficiency of the palladium catalysed hydroformylation process required a comparison with the hydroformylation processes based on cobalt and rhodium. Variation of ligands (diphosphines of the type R2P(CH2)nPR2), solvents, acids, etc. had a dramatic effect on the products and the rate of the reaction. In the presence of trifluoroacetic acid 1-pentene is converted to C-6 aldehydes, while in the presence of trifluoromethanesulfonic acid 1-pentene is converted to C-11 ketones. Corresponding results were obtained with 1-octene as substrate. The palladium catalysts were found to also effect isomerisation of the a- olefin into internal olefins, but isomerisation was not a rate limiting process with respect to the hydroformylation reaction. Palladium catalysed isomerisation reactions occurred at a slower rate than the corresponding cobalt catalysed isomerisation process. However, with rhodium no isomerisation occurred. The comparison between cobalt, rhodium and palladium showed that rhodium is the best catalyst for the hydroformylation of a-olefins. The pressures and temperatures required for this process are much lower than that required for palladium and cobalt. The ligand used is triphenylphosphine, which is relatively inexpensive and non-toxic,in contrast with the more expensive ligands required for the cobalt and palladium hydroformylation processes. The use of palladium opens up the unique possibility of converting a-olefins into “dimeric” ketones, which show promise as precursors for the new class of geminidetergents. / Prof. C.W. Holzapfel rhodium catalysts alkenes hydroformylation carbonyl compounds palladium catalysts organic compounds synthesis
242	Metal nanoparticles as catalysts for alkene hydrosilylation / Nanoparticules de métaux comme catalyseurs pour l'hydrosilylation des alcènes Galeandro-Diamant, Thomas 15 December 2016 (has links) L'hydrosilylation des alcènes est une méthode cruciale de formation de liaisons carbone-silicium. Elle est utilisée industriellement pour la production de fluides silicones fonctionnels et d'élastomères silicones. Les procédés actuels d'hydrosilylation des alcènes utilisent des complexes de platine comme catalyseurs. Bien que ces complexes soient extrêmement efficients, ils ne sont d'habitude pas récupérés en fin de réaction, ce qui rend leur utilisation coûteuse et peu durable, étant donnée la rareté du platine. Dans ce projet, nous avons synthétisé et testé plusieurs types de nanoparticules métalliques comme catalyseurs pour l'hydrosilylation des alcènes, dans un effort vers des catalyseurs durables. D'abord, nous avons synthétisé des nanoparticules de platine de 2 nm de diamètre et les avons comparées avec le complexe de Karstedt, le catalyseur de référence en hydrosilylation des alcènes. Nous avons montré que les nanoparticules de platine étaient aussi efficientes que le complexe de Karstedt dans des conditions proches des conditions industrielles, malgré leur dispersion métallique plus faible. Ces observations ont réactivé le débat sur la nature réellement homogène ou colloïdale du complexe de Karstedt pendant la catalyse. Ensuite, un catalyseur hétérogène à base de platine, résistant à la lixiviation, a été développé, basé sur l'encapsulation de nanoparticules de platine dans la matrice d'une silice mésostructurée, la SBA-15. Enfin, d'autres catalyseurs alternatifs ont été développés, basés sur d'autres métaux / Alkene hydrosilylation is a crucial method of forming carbon-silicon bonds. It is used industrially for the production of functional silicone fluids and silicone elastomers. The current industrial alkene hydrosilylation processes use platinum complexes as catalysts. Although these complexes are extremely efficient, they are usually not recovered at the end of the synthesis, making their use expensive and unsustainable, given the scarcity of platinum. In this work, we have synthesized and evaluated several kinds of metal nanoparticles as catalysts for alkene hydrosilylation, in a quest towards sustainable catalyts. First, we have synthesized platinum nanoparticles of 2 nm diameter and compared them with Karstedt's complex, the benchmark catatalyst in alkene hydrosilylation. It was shown that platinum nanoparticles were as efficient as Karstedt's complex in industrially relevant hydrosilylation conditions, despite their lower metal dispersion. These findings reactivated the debate on whether's Karstedt's complex was truly homogeneous or colloidal during catalysis. Then, a leaching-resistant heterogeneous platinum catalyst was developed, based on the embedding of platinum nanoparticles in the matrix of a mesostructured silica, SBA-15. Finally, other alternative catalytic systems were developed, based on other metals Nanoparticules Métaux Hydrosilylation Alcènes Silicones Nanoparticles Metals Hydrosilylation Alkenes Silicones 660
243	Studies On Catalytic Oxygen Transfer Reactions In Organic Synthesis Kesavan, V 01 1900 (has links) (PDF) No description available. Organic Compounds - Synthesis Oxidation Olefins Ruthenium(I1) Complex Alkenes Cycloalkanes Epoxidation Aerobic Oxidation Organic Chemistry
244	Systèmes hybrides photosensibilisateur-laccase pour la catalyse d'oxydation de composés organiques / Hybrid photosensitizer-laccase systems for the oxidation of organic compounds Schneider, Ludovic 17 December 2014 (has links) Les laccases sont des enzymes de type oxydase, réalisant de manière efficace la réduction du dioxygène en eau. Des études réalisées au laboratoire ont permis de montrer que l’irradiation sous atmosphère inerte d’un système de type, EDTA/[Ru(bpy)3]2+/laccase, conduisait à la photoréduction de l’enzyme via la formation d'une espèce [Ru(bpy)3]2+. La substitution de l’EDTA par un alcène de type p-styrène sulfonate conduit également à la photoréduction de l’enzyme. L'ouverture à l'air du système permet une consommation d’oxygène concomitante à la détection par RMN de produits d’oxydation tels que l’époxyde, le diol et le p-benzaldéhyde sulfonate. L’influence de la concentration des différents partenaires, de la source d’irradiation et du pH sur l’efficacité de cette réaction a été évaluée. D’autres alcènes tels que le styrène, le cyclohéxène ou le cyclooctène sont également substrats. Le marquage isotopique en présence soit d'H218O soit d'18O2 ainsi que l’utilisation de générateurs d’espèces réactives de l’oxygène, ont permis de proposer un mécanisme majoritaire où l’espèce RuIII, photoproduite avec l'assistance de la laccase, pourrait arracher un électron du substrat qui à son tour réagirait avec le dioxygène présent dans le milieu pour conduire aux produits observés. D’autres complexes photoactivables à base de ruthénium ou de manganèse ont également été employés. Afin d’aborder le contrôle de la réactivité, le greffage covalent d’un photosensibilisateur à base de ruthénium sur une lysine unique à proximité du site d'oxydation des substrats de l'enzyme a été effectué. / Laccases are oxidases that efficiently perform the reduction of dioxygen into water. Studies in the laboratory have allowed to show that irradiation under inert atmosphere of a EDTA/[Ru(bpy)3]2+/laccase system, lead to the photoreduction of the enzyme via the irradiation of [Ru(bpy)3]2+. The substitution of EDTA by the alkene p-styrene sulfonate results similarly in a photoreduction of the enzyme. Opening the system to air allows a dioxygen consumption with a simultaneous detection of oxidation products such as the epoxide, diol and p-benzaldehyde sulfonate detected by NMR. The influence of the concentration of the partners, the irradiation source and pH on the efficiency of the reaction was evaluated. Other alkenes such as styrene, cyclohexene and cyclooctene are also substrates. Isotopic labeling experiments in the presence of either H218O or 18O2, as well as the use of reactive oxygen species generators, allowed us to propose a main mechanism where the laccase assisted RuIII photogenerated specie would withdraw an electron from the substrate which in turn would react with dioxygen to yield the products observed. Other ruthenium and manganese photosensitizers were also used. To address the control of the reactivity, a covalent grafting of a ruthenium photosensitizer, on a unique lysine nearby the substrate oxidation site of the laccase was done. Oxygénation Dioxygène Styrène Alcènes Ruthénium Laccase Oxygenation Dioxygen Styrene Alkenes Ruthenium Laccase
245	Étude théorique des mécanismes de combustion des alcènes à basse température / Theoretical study of the mechanisms of combustion of alkenes at low temperature Lizardo Huerta, Juan Carlos 25 March 2015 (has links) Ce travail de thèse a porté sur l'étude des réactions unimoléculaires de décomposition des alcènes à basse température. L'oxydation de ces molécules est primordiale dans la compréhension des mécanismes de combustion, car elles peuvent être présentes initialement dans des carburants usuels ou formées en tant qu'intermédiaires dans le processus d'oxydation. L’étude théorique menée peut se décomposer en deux parties : - L’étude des réactions de décomposition des radicaux hydroxyalkylperoxyles (HOROO•) obtenus à partir de l’addition d’un radical •OH sur l’alcène, suivi par une addition du radical •ROH sur l’oxygène moléculaire. Cette étude a été conduite de façon systématique sur un ensemble de radicaux représentatifs d'alcènes afin de mettre en évidence l'influence de l'environnement intramoléculaire sur les constantes de vitesse. Les résultats obtenus ont montré l’influence très nette de certains paramètres comme la présence d'un groupement hydroxyle en position β par rapport à l'atome de carbone réactif, la nature des atomes de carbone portant les hydrogènes transférés, la taille des cycles de transition ou encore la présence d'une liaison hydrogène intramoléculaire. - L’étude des réactions de décomposition unimoléculaires des radicaux allylperoxyles obtenus à partir de l’addition des radicaux allyliques sur l’oxygène. La grande complexité de ces systèmes a été mise en avant au cours de ce travail. Il a ainsi pu être mis en évidence que la formation d'un composé de type 1-alcenyloxirane est favorisée à basse température ce qui montre l'importance de ces réactions, souvent négligées dans les modèles / This work focused on the study of the unimolecular decomposition of the low-temperature reactions of alkenes. The oxidation of these molecules is essential in the understanding of the mechanisms of combustion, because they are initially present in conventional fuels or formed as intermediates in the oxidation process. The theoretical study can be divided in two parts: - The study of the decomposition of hydroxyalkylperoxyl radicals (HOROO•) obtained from the addition of an •OH radical on the alkene, followed by a subsequent addition of the formed radical •ROH on molecular oxygen. This study was conducted in a systematic way on a set of representative radicals of alkenes in order to highlight the influence of the intramolecular environment on the rate constants. The results clearly showed the major influence of parameters such as the presence of a hydroxyl group in β position with respect to the reactive carbon atom, the nature of the carbon atoms bearing the transferred hydrogen, the size of the transition state ring and the presence of intramolecular hydrogen bonds. - The study of the unimolecular decomposition of the allylperoxy radicals obtained from the addition of a resonance-stabilized radical on molecular oxygen. The complexity of these systems, specifically induced by the mesomeric structures of heavy allyl radicals and the role of cis and trans conformations alkenes parents, have been highlighted in this work. It has been shown that the formation of a compound 1-alkenyloxirane is favored at low-temperatures, which shows the importance of these reactions, usually neglected in the kinetic models for the combustion of alkenes Combustion Alcènes Chimie quantique TST Combustion Alkenes Quantum chemistry TST 621.402 3 541.28 547.01
246	Rhodium(III)-catalyzed Difunctionalization of Alkenes Initiated by Carbon–Hydrogen Bond Activation Phipps, Erik Johann Thorngren January 2021 (has links) The direct conversion of carbon–hydrogen bonds into valuable carbon-carbon and carbon-heteroatom bonds is a significant challenge to synthetic organic chemists. More than ever, chemists are employing Rh(III)-catalysts bearing cyclopentadienyl (Cp) ligands to transform otherwise inert C–H bonds. Furthermore, manipulating the sterics and electronics of the Cp ligand show significant impact on catalytic transformations. Our group has developed a library of CpˣRh(III)-precatalysts in hopes of enhancing known reactivity as well as discovering new C–H bond functionalizations. We have previously reported that N-enoxyphthalimides are a unique one-carbon component for the cyclopropanation of activated alkenes. In an effort to expand the scope to accessible alkenes, we have found a number of symmetrical unactivated alkenes undergo [2+1] annulation to afford intriguing spirocyclic cyclopropanes. Additionally, we have developed a Rh(III)-catalyzed diastereoselective [2+1] annulation onto allylic alcohols to furnish substituted cyclopropyl ketones. Notably, the traceless oxyphthalimide handle serves three functions: directing C–H activation, oxidation of Rh(III), and, collectively with the allylic alcohol, in directing cyclopropanation to control diastereoselectivity. Allylic alcohols are shown to be highly reactive olefin coupling partners leading to a directed diastereoselective cyclopropanation reaction, providing products not accessible by other routes. Next, an artifact of previous cyclopropanation reactions leads to the formation of a Rh-π-allyl complex. Attempts at 1,1-carboamination of alkenes are made using alkenes and nitrenoid precursors toward the 3-component synthesis of allylic amines. Stoichiometric studies help elucidate the mechanism and challenges. Lastly, efforts toward 1,2-carboamination of alkenes initiated by sp³ C–H bond activation are made with two different reactivity manifolds. Isolation of reaction intermediates are discussed as well as providing viable paths toward valuable products. Chemistry, Organic Chemistry Rhodium Ligand binding (Biochemistry) Cyclopropane Allyl alcohol Alkenes
247	Asymmetric Dihydroxylation and Aziridination of Allenes and Related Chemistry Liu, Renmao 11 May 2007 (has links) (PDF) A novel method for asymmetric synthesis of α-hydroxy ketone with excellent regio- and stereoselectivity has been established by the systematic investigation of asymmetric dihydroxylation of allenes. The efficiency of kinetic resolution of racemic allenes was also investigated by using the AD reaction on both 1,3-disubstituted and trisubstituted allenes. Steric effects, electronic effects and allene substitution are also discussed. Aziridines were formed by copper-catalyzed intramolecular nitrene addition to alkenes. The carbamate group was used as the tether between the alkene and the nitrene. Subsequent nucleophilic attack of the aziridine was accomplished using RSH, R2NH, N3-,or ROH as the nucleophile. This addition was found to be regio- and stereoselective. This methodology has provided a new strategy for the stereoselective construction of three adjacent functional groups, in particular the 1,2 diamino-3-hydroxy unit. The rhodium-catalyzed intramolecular aziridination of allenic N-sulfonyloxy carbamates has been established. Efficient ring opening of these bicyclic compounds may provide synthetic utility in organic chemistry. The intramolecular aziridination of allenic sulfamate esters was tested on a single example to afford in situ a ring opened product. asymmetric dihydroxylation aziridination allenes alkenes α-hydroxy ketone aziridines Biochemistry Chemistry
248	Highly Stereoselective Cyclopropanation of Alkenes with Unsymmetrical Diazomalonates via Co(II)-Based Metalloradical Catalysis: Wang, Jingyi January 2021 (has links) Thesis advisor: Xiaoxiang Peter Zhang / Thesis advisor: James P. Morken / Diazomalonates have been demonstrated, for the first time, as effective radical precursors for asymmetric radical cyclopropanation of alkenes via Co(II)-based metalloradical catalysis (MRC). With an optimized D2-symmetric chiral amidoporphyrin as the supporting ligand, the Co(II)-based metalloradical system can efficiently activate unsymmetrical methyl phenyl diazomalonate (MPDM) for the asymmetric cyclopropanation of alkenes, enabling stereoselective construction of 1,1-cyclopropanediesters bearing two contiguous chiral centers, including at least one all-carbon quaternary stereogenic center. The Co(II)-catalyzed asymmetric cyclopropanation, which operates at room temperature without slow addition of the diazo compound, is generally applicable to a broad range of olefin substrates and tolerates various functionalities, providing a streamlined synthesis of chiral 1,1-cyclopropanediesters in high yields with high level of control in both diastereoselectivity and enantioselectivity. Mechanistic studies on the cyclopropanation reactions, including the use of (E)- and (Z)-b-deuterostyrenes, support the underlying stepwise radical pathway for the Co(II)-catalyzed cyclopropanation. In addition to functioning as effective 1,3-dipoles for stereospecific formation of five-membered ring structures, the resulting enantioenriched methyl phenyl (E)-1,1-cyclopropanediesters serve as useful building blocks for the synthesis of different 1,1-cyclopropanediesters, 1,1-cyclopropaneestercarboxylic acids and 1,1-cyclopropaneesteramides while maintaining the original stereochemistry. Additionally, the enantioenriched (E)-1,1-cyclopropanediesters can be converted to (Z)-diastereomers without affecting the high enantiopurity. / Thesis (PhD) — Boston College, 2021. / Submitted to: Boston College. Graduate School of Arts and Sciences. / Discipline: Chemistry. Asymmetric Cyclopropanation of Alkenes Cobalt Catalyst Metalloradical Catalysis (MRC) Methyl Phenyl Diazomalonate (MPDM) Stereoselectivity Synthesis
249	<b>Catalytic STEREOSELECTIVE </b>β<b>–Elimination Reactions using Cobalt Vinylidenes</b> Vibha Vijayakumar Kanale (18120484) 08 March 2024 (has links) <p dir="ltr">Ring strain is the driving force for numerous ring-opening reactions of three- and four-membered heterocycles. By comparison, five-membered heterocycles lack this thermodynamic driving force. As a result, only a few methods exist for the ring-opening of five-membered heterocycles using transition metal catalysts. For unstrained and unactivated 2,5-dihydrofurans this is achieved via a β-O elimination process, wherein, gaining selectivity over a competing β-H elimination is challenging. We report a novel strategy for the asymmetric ring-opening of 2,5-dihydrofurans with dichloroalkenes utilizing an earth-abundant cobalt catalyst. We propose that the dichloroalkenes form reactive vinylidene intermediates with the chiral catalyst, followed by a [2+2] cycloaddition with the heterocyclic alkene. This cobaltacyclobutane exclusively undergoes an outer-sphere β-O elimination assisted by zinc halide. Alternative inner-sphere β-O and β-H elimination pathways are inaccessible from this four-membered metallacycle. This is followed by a transmetallation step to form a zinc metallacycle, which subsequently gives rise to homoallylic alcohols, upon quenching, with high diastero- and enantioselectivity. Additionally, the organozinc intermediate can be trapped in situ by various electrophiles for further derivatizations. DFT model predicts the origin of the high diastereo- as well as enantioselectivity observed in the reaction.</p><p dir="ltr">Furthermore, the cobaltacyclobutane intermediate serves as a dynamic platform, facilitating access to a diverse array of products depending on the alkene partners employed. Utilizing chiral allylic alcohols as alkene partners leads to the translation of stereochemical information enabling the stereospecific synthesis of both <i>E</i>- and <i>Z</i>-isomers of alkenes. Alkenes are important motifs found in various natural products and bioactive compounds. A catalytic approach for the precise control of the alkene geometry is highly valuable since the stereochemistry of alkenes plays a pivotal role in determining the properties of molecules. Our strategy provides access to organozinc dienes which could be functionalized further to form highly substituted 1,4-skipped dienes. Additionally, meso-diols can undergo a desymmetrizing β-O elimination from the cobaltacyclobutane intermediate yielding chiral cyclopentenols with contiguous stereocenters</p> Organic chemical synthesis Catalysis and mechanisms of reactions Steroselective Enantioselective Alkenes Ring opening Unstrained heterocycle
250	Refinements in the isomer distribution and relative rate of sulfonation of toluene and hydrochlorination of olefins with stannic chloride catalyst Guillot, David George 01 May 1966 (has links) The sulfonation of toluene at -12.5° C. with sulfur trioxide in liquid sulfur dioxide was found to give 10.03 ± 0.20 % ortho, 0.73 ± 0.20 % meta and 89.24 ± 0.20 % para isomers. This isomer distribution was determined by isotope dilution analysis using sulfur-35 enriched sulfur trioxide. After dilution of aliquots of the neutralized sulfonation mixture with pure sodium salts of each of the isomers prepared from the corresponding toluidines, the isomers were converted to the p-toluidine salts, purified by recrystallization, and counted by liquid scintillation counting. The relative rate of sulfonation of toluene compared to benzene was studied under the same conditions. The analysis in this case was accomplished by ultraviolet spectrophotometry. The only assumption made was that the isomer distribution of toluene does not change when benzene is added during the sulfonation. The results show that the relative rate (kt/kb) is 10.9 ± 1,5 at low benzene to toluene ratios but increases considerably at high ratios. The hydrochlorination of cyclohexerte, cis-2-butene and trans-2-butene with stannic chloride catalyst was studied in n-heptane solvent. The kinetics were found to be considerably influenced by trace impurities, especially moisture. The kinetics were found to be first order in olefin and stannic chloride and from zero to three and one-half order in hydrogen chloride depending on the amount of moisture present. When moisture is absent, unexplained abnormal kinetics occurred. Polymerization, cyclization, alkylation, and dehydrochlorination were insignificant under the conditions of the kinetic experiments. Isomerism Chemistry Physical and theoretical Sulfonation Toluene Alkenes Chemistry Physical Sciences and Mathematics

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