Global ETD Search

21	Studies on Reactions Promoted by Photo-generated Bromine Radical / 光で生じる臭素ラジカルが促進する反応に関する研究 Kawasaki, Tairin 23 March 2022 (has links) 京都大学 / 新制・課程博士 / 博士(工学) / 甲第23925号 / 工博第5012号 / 新制\|\|工\|\|1782(附属図書館) / 京都大学大学院工学研究科合成・生物化学専攻 / (主査)教授村上正浩, 教授杉野目道紀, 教授中尾佳亮 / 学位規則第4条第1項該当 / Doctor of Philosophy (Engineering) / Kyoto University / DFAM Transition Metal Catalysis Photoredox Catalysis Hydrogen Atom Transfer Dehydrogenation Coupling Reaction 500
22	Experimental and Computational Studies on Ruthenium- and Manganese-Catalyzed C-H and C-C Activation Rogge, Torben 30 October 2019 (has links) No description available. 540 Transition Metal Catalysis Reaction mechanism Ruthenium Manganese DFT calculations C-C Activation C-H Activation Reaction Kinetics Chemie (PPN62138352X)
23	Development of Photo-Induced C–H Activation by Copper and Ruthenium Catalysis Koeller, Julian 29 October 2019 (has links) No description available. 540 arylation ruthenium photocatalysis meta-selective alkylation chalcogenation C–H activation copper transition metal catalysis photo-induced Chemie (PPN62138352X)
24	Studies Towards the Discovery of Antibacterial Natural Products and the Development of a Novel Ruthenium-Catalyzed Homo Diels-Alder [2+2+2] Cycloaddition Kettles, Tanner James 19 April 2012 (has links) The isolation and identification of the active constituents from an Allium sp. extract possessing antibacterial activity was undertaken. The plant material of interest was extracted, purified and screened for antibacterial activity against a Gram positive bacteria. Multiple trials were performed and the isolation was scaled-up repeatedly, overall three compounds potentially possess the observed activity. One compound was identified to yield the majority of activity, and a refined procedure for its purification was established. Initial characterization studies demonstrated the major isolate of interest is novel compared to other isolates from the Allium genus. A ruthenium-catalyzed homo Diels-Alder [2+2+2] cycloaddition between bicyclo[2.2.1]hepta-2,5-diene and alkynyl phosphonates was also studied. The observed reactivity was found to be dependent on the presence of the phosphonate moiety. The cycloaddition was compatible with a variety of aromatic and aliphatic substituted alkynyl phosphonates providing the corresponding phosphonate substituted deltacyclenes in low to good yields (up to 88%). Natural products Organic chemistry Cycloadditions Bicyclic alkenes Allium isolation homo Diels-Alder [2+2+2] Compound isolation transition metal catalysis
25	Synthetic Studies on Palladium-Catalyzed Olefin Dioxygenation, Indole Functionalization, and Helical Ligands Antonic, Marija 15 December 2009 (has links) Palladium-catalyzed olefin dioxygenation is a powerful tool in the generation of complex and valuable substrates, one which may become complimentary to the well known Sharpless dihydroxylation. In this work the mechanism of this transformation is examined via reaction kinetics and Hammett studies, which corroborate a PdII/IV catalytic cycle and suggest that the rate determining step is the oxidation of PdII to PdIV. Olefin dioxygenation was also found to proceed in the presence of catalytic quantities of BF3•OEt2 or triflic acid, with stoichiometric hypervalent iodine oxidant and an acetic acid solvent. Furthermore, asymmetric variants of intramolecular palladium-catalyzed olefin dioxygenation were also investigated, which resulted in the formation of tetrahydrofuran products in up to 36% ee. Next, chelate-assisted C–H bond functionalization of indoles at the C7 position and of carbazoles at the C1 position was investigated with a variety of arylation, halogenation and oxygenation techniques. Lastly, our efforts towards the synthesis of a mono-phosphine based [5]helicene ligand via olefin metathesis and photocyclization strategies will be discussed. palladium catalysis olefin dioxygenation indole functionalization helical ligand vicinal oxidation hammett study synthetic organic chemistry transition metal catalysis 0490
26	Synthetic Studies on Palladium-Catalyzed Olefin Dioxygenation, Indole Functionalization, and Helical Ligands Antonic, Marija 15 December 2009 (has links) Palladium-catalyzed olefin dioxygenation is a powerful tool in the generation of complex and valuable substrates, one which may become complimentary to the well known Sharpless dihydroxylation. In this work the mechanism of this transformation is examined via reaction kinetics and Hammett studies, which corroborate a PdII/IV catalytic cycle and suggest that the rate determining step is the oxidation of PdII to PdIV. Olefin dioxygenation was also found to proceed in the presence of catalytic quantities of BF3•OEt2 or triflic acid, with stoichiometric hypervalent iodine oxidant and an acetic acid solvent. Furthermore, asymmetric variants of intramolecular palladium-catalyzed olefin dioxygenation were also investigated, which resulted in the formation of tetrahydrofuran products in up to 36% ee. Next, chelate-assisted C–H bond functionalization of indoles at the C7 position and of carbazoles at the C1 position was investigated with a variety of arylation, halogenation and oxygenation techniques. Lastly, our efforts towards the synthesis of a mono-phosphine based [5]helicene ligand via olefin metathesis and photocyclization strategies will be discussed. palladium catalysis olefin dioxygenation indole functionalization helical ligand vicinal oxidation hammett study synthetic organic chemistry transition metal catalysis 0490
27	Studies towards the nucleophilic dearomatisation of electron-deficient heteroaromatics and hydrogen borrowing reactions of methanol Poole, Darren L. January 2014 (has links) <strong>Introduction – Dearomatisation of Heteroaromatic Compounds</strong> The introduction provides a survey of dearomatisation reaction of heteroaromatics, with a particular focus on pyridines/pyridinium salts and furans. The mechanism, scope, and limitations of various approaches are covered, along with the goals of this project. <strong>Results and Discussion – Dearomatisation of Electron-Deficient Heteroaromatics</strong> This chapter initially explores the asymmetric addition of organometallic nucleophiles to pyridinium salts bearing a chiral counterion. Unfortunately, this approach ultimately proved unsuccessful, due to low observed enantioselectivities, and the low solubility of such salts. The second part of this chapter concerns the attempted asymmetric addition of dicarbonyl nucleophiles to electron-deficient furans, under conditions of chiral phase-transfer catalysts, affording bicyclic products in moderate enantioselectivity. Various alternative routes were also explored for the dearomatisation of furans and benzenoid systems. <strong>Introduction – Hydrogen Borrowing Alkylation Reactions with Alcohols</strong> The introduction surveys the range of methods available for the alkylation of various nucleophiles with alcohols under transition metal-catalysed conditions. Related methodologies are also explored, along with methods for the dehydrogenation of methanol. <strong>Results and Discussion - Rhodium-catalysed Methylation of Ketones Using Methanol</strong> This chapter describes the development of a novel ketone α-methylation using methanol. The development of reaction conditions is explored, followed by expansion of the substrate scope, including limitations of the methylation reaction. Mechanistic investigations support a methanol oxidation, aldol reaction/elimination, conjugate reduction pathway. Investigations into the role of O2 in the methylation reaction proved inconclusive. The utility of the reaction was also expanded via one-pot dialkylation reactions (work by Di Shen), Baeyer-Villiger oxidation of the products, and an attempted asymmetric transfer-hydrogenation. <strong>Results and Discussion - Interrupted Hydrogen Borrowing Reactions of Methanol</strong> This chapter looks to intercept intermediates from the α-methylation reaction. The selective methylenation of ketones is described, and a range of nucleophiles are screened for further functionalisation of ketones. Finally, a number of nucleophiles, including nitroalkanes, amines, peroxides and boronic acids are applied to one pot methylenation/conjugate addition protocols, affording complex products after two steps in one reaction vessel. <strong>Experimental</strong> Full experimental procedures and spectroscopic characterisation of compounds are provided. 547
28	Réactivités de N-Tosylhydrazones : application à la Synthèse d’Analogues de l’isoCombrétastatine A-4 / N-Tosylhydrazones : towards the synthesis of isocombretastatin A-4 analogues Aziz, Jessy 24 November 2014 (has links) Les travaux rapportés dans ce mémoire concernent le développement de la réactivité de N-tosylhydrazones dans la création de liaisons carbone-carbone et carbone-azote ainsi que leurs applications à la synthèse des analogues de l’isocombrétastatine A-4 (isoCA-4), aux propriétés antivasculaires.Au cours de ce travail, des molécules de type 1,1-diaryléthylène furent synthétisées par un couplage pallado-catalysé entre des N-tosylhydrazones et des aryles halogénés. Ainsi, des oléfines polysubstituées avec un motif alcoxyle, analogues de l’isoCA-4, ont présenté des activités biologiques intéressantes. De même, les N-tosylhydrazones constituent des intermédiaires pour la synthèse de 1,5-énynes aromatiques. La cyclisation de ces derniers a pu être contrôlée selon la nature du catalyseur utilisé. En effet, en présence de l’or comme catalyseur, une cyclisation 6-endo-dig majoritaire est obtenue alors qu’en présence du palladium, une cyclisation 5-exo-dig exclusive est observée. Cette méthode permettrait de synthétiser des analogues contraints de l’isoCA-4. Le couplage réducteur, catalysé au cuivre, entre des N-tosylhydrazones et des amines et conduisant à des motifs arylalkylamines fut développé. Enfin, un processus cascade entre des 2’-halogéno-biaryl- N-tosylhydrazones et des amines fournit des dérivés du fluorène par la création d’une liaison CN et d’une liaison CC sur le même atome carbénique. / This manuscript reports the development of new metal-catalyzed reactions using N-tosylhydrazones as coupling partners for the creation of carbon-carbon and carbon-nitrogen bonds. These reactions are applied in the synthesis of analogues of isocombretastatine A-4 (isoCA-4), a vascular disrupting agent.First, a palladium-catalyzed cross-coupling reaction between N-tosylhydrazones and aryl halides was developed. By this means, polysubstituted olefins with an alkoxy motif were synthesized and presented good biological activities. Then, aromatic 1,5-enynes were synthesized by a multi-step approach using N-tosylhydrazones as intermediates. The regioselectivity of the cyclisation of these enynes was controlled depending on the reaction conditions. Under gold catalysis, a major 6-endo-dig cyclisation pattern leads to naphthalene derivatives while under palladium catalysis; an exclusive 5-exo-dig cyclisation furnishes benzofulvène derivatives. Conformationnally restricted isoCA-4 analogues could be synthesized by applying this method. A copper-catalyzed reductive coupling between N-tosylhydrazones and amines leading to -branched amine derivatives was also developed. Finally, a cascade reaction between 2’-halo-biaryl-N-tosylhydrazones and amines furnished fluoren scaffold by the formation of CC and CN bonds on the same carbenic atom. N-tosylhydrazones Catalyse métallique Palladium Cuivre Liaisons C-C et C-N Isocombrétastatine A-4 N-tosylhydrazones Transition metal catalysis Palladium Copper C-C and C-N bonds Isocombretastatine A-4
29	Transition Metal Catalysis: Activation of CO2, C–H, and C–O Bonds En Route to Carboxylic Acids, Biaryls, and N-containing Heterocycles Yeung, Charles See Ho 12 January 2012 (has links) Transition metal catalysis is a powerful tool for the construction of biologically active and pharmaceutically relevant architectures. With the challenge of continually depleting resources that this generation of scientists faces, it is becoming increasingly important to develop sustainable technologies for organic synthesis that utilize abundant and renewable feedstocks while minimizing byproduct formation and shortening the length of synthetic sequences by removing unnecessary protecting group manipulations and functionalizations. To this end, we have developed four new methods that transform inexpensive starting materials to valuable products. This dissertation covers the following key areas: 1) activation of CO2 for a mild and functional group tolerant synthesis of carboxylic acids, 2) oxidative twofold C–H bond activations as a strategy toward biaryls, 3) migratory O- to N-rearrangements in pyridines and related heterocycles for the preparation of N-alkylated heterocycles, and 4) asymmetric hydrogenations of cyclic imines and enamines en route to chiral 1,2- and 1,3-diamines and macrocyclic peptides. organic chemistry synthesis transition metal catalysis carbon dioxide organozinc reagents carboxylic acids nickel C-H activation biaryls palladium heterocycles ruthenium diamines cyclic peptides asymmetric hydrogenation rhodium 0490
30	Transition Metal Catalysis: Activation of CO2, C–H, and C–O Bonds En Route to Carboxylic Acids, Biaryls, and N-containing Heterocycles Yeung, Charles See Ho 12 January 2012 (has links) Transition metal catalysis is a powerful tool for the construction of biologically active and pharmaceutically relevant architectures. With the challenge of continually depleting resources that this generation of scientists faces, it is becoming increasingly important to develop sustainable technologies for organic synthesis that utilize abundant and renewable feedstocks while minimizing byproduct formation and shortening the length of synthetic sequences by removing unnecessary protecting group manipulations and functionalizations. To this end, we have developed four new methods that transform inexpensive starting materials to valuable products. This dissertation covers the following key areas: 1) activation of CO2 for a mild and functional group tolerant synthesis of carboxylic acids, 2) oxidative twofold C–H bond activations as a strategy toward biaryls, 3) migratory O- to N-rearrangements in pyridines and related heterocycles for the preparation of N-alkylated heterocycles, and 4) asymmetric hydrogenations of cyclic imines and enamines en route to chiral 1,2- and 1,3-diamines and macrocyclic peptides. organic chemistry synthesis transition metal catalysis carbon dioxide organozinc reagents carboxylic acids nickel C-H activation biaryls palladium heterocycles ruthenium diamines cyclic peptides asymmetric hydrogenation rhodium 0490

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