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1	Asymmetric Carbon-Carbon Bond Formation Via 3,3'-Reductive Elimination of Allyl Palladium Complexes Brozek, Laura January 2011 (has links) Thesis advisor: James P. Morken / This dissertation describes the development of two enantioselective methods of carbon-carbon bond formation. Chapter one discusses the development of an enantioselective Pd(0)-catalyzed conjugate addition of allylboronic acid pinacol ester to α,β-unsaturated methylidene ketones. Utilizing the same rationale for regio- and enantiocontrol as in the related enantioselective conjugate allylation of arylidene ketones, this method addresses the gap in technology by expanding the scope of the reaction to include alkyl-substituted enones. Chapter two examines the coupling of allyl electrophiles and allyl metal reagents. With computational insight into the reaction mechanism, a catalyst system was designed to control regioselectivity and enantioselectivity. Isotope labeling studies were carried out to probe the mechanism of the transformation. The reaction also proves to be diastereoselective when a substituted allyl boron reagent is employed. / Thesis (PhD) — Boston College, 2011. / Submitted to: Boston College. Graduate School of Arts and Sciences. / Discipline: Chemistry. 3 3'-Reductive Elimination Allylation Allylmetal Asymmetric Catalysis
2	Synthesis and Characterization of a Novel Platinum Ligand Complex ((κ-N,C,N- 2,6-bis(diethylaminomethyl)phenyl)(4- tert-butylphenyl) platinum(II)) Roleder, Carly 01 January 2018 (has links) A novel platinum ligand complex (NCN)PtAr, ((κ-N,C,N- 2,6-bis (diethylaminomethyl)phenyl)(4- tert-butylphenyl) platinum(II)), was synthesized. A reaction of 1-Bromo-4-tert-butylbenzene Grignard with (NCN)PtCl, (where NCN = 2,6-bis(diethylaminomethyl)phenyl) yielded the (NCN)PtAr (where Ar = 4-tert-butylphenyl). The product was then characterized with NMR spectra through 1H NMR, 13C NMR, COSY, HSQC, and HMBC to verify it structure. Inorganic Chemistry Reductive Elimination Platinum synthesis Inorganic Chemistry
3	Synthesis of Enantioenriched 1,5-Dienes and 1,5-Enynes by a Palladium-Catalyzed 3,3'-Reductive Elimination: Methodology Development and Mechanistic Studies Ardolino, Michael Joseph January 2014 (has links) Thesis advisor: James P. Morken / This dissertation details the development, application and study of new palladium-catalyzed carbon-carbon bond forming strategies that generate synthetically useful enantioenriched small molecules. Controlled by a bidentate phosphine ligand, these transformations are thought to operate through a unique 3,3'-reductive elimination that leads to high regio- and stereoselectivity. Specifically, Chapter 1 introduces background on prior work that led to the first allyl-allyl coupling to deliver branched 1,5-dienes, and presents new computational studies on the origins of regioselectivity with mono- and bidentate ligands. Building on these studies, Chapter 2 describes the development of a diastereoselective allyl-allyl coupling of substituted allylboron reagents with allylic chloride electrophiles. To extend the scope of allyl-allyl coupling, Chapter 3 details further reaction optimization and mechanistic studies that have allowed for increasingly congested bond formations. In Chapter 4, a related allyl-propargyl coupling to give enantioenriched 1,5-enynes through stereospecific reactions and kinetic resolution is presented. These developments are accompanied by laboratory and computational data that provide a deeper understanding of reaction mechanisms and the origins of regio- and stereoselectivity. / Thesis (PhD) — Boston College, 2014. / Submitted to: Boston College. Graduate School of Arts and Sciences. / Discipline: Chemistry. Allyl-Allyl Cross-Coupling Enantioselective Palladium 1,5-Dienes 1,5-Enynes 3,3'-Reductive Elimination
4	Development of catalytic asymmetric allylation of dienone Yao, Li January 2008 (has links) Thesis advisor: James P. Morken / The catalytic allylation of aldehydes, ketones, and imines is a very useful reaction for the formation of a new carbon-carbon bond in synthetic organic chemistry. There have been several successful reports of catalytic asymmetric reactions that use aldehydes as the substrate. However, there have been very few successful examples with ketones. Herein, a nickel-catalyzed allylation of dienones with the pinacol ester of allylboronic acid is presented. Based on 3,3’-reductive elimination, the relationship between the dienone structure and 1,2- and 1,6-regioselectvity has been studied. The development of a catalyzed asymmetric 1,2 allylation of dienones is also presented. / Thesis (MS) — Boston College, 2008. / Submitted to: Boston College. Graduate School of Arts and Sciences. / Discipline: Chemistry. allylation of dienone nickel-catalyst 1,2-addition asymmetric 1,6-addition 3,3-reductive elimination
5	Organometallic Chemistry Supported by the PNP Pincer Framework for Both Early and Late Transition Metals Brammell, Christina 1987- 14 March 2013 (has links) Tridentate "pincer" ligands provide a unique balance of stability and reactivity in organometallic chemistry. The development of diarylamido-based PNP pincer ligands has led to many applications in catalysis, including the potential to facilitate unique chemical transformations at transition metal centers. The main objective of this thesis was to explore transition metal chemistry supported by the PNP pincer framework for both early and late transition metals. In Chapter I, the history behind the design and synthesis of pincer complexes is described. The advantages and disadvantages of various pincer ligands are reviewed to show the reasoning behind the synthesis of the PNP pincer framework. Chapter II discusses the synthesis of novel Hf and Ta complexes involving the PNP ligand. Reactions of (PNP)HfCl3 with large alkyl Grignards led to double alkylation and triple alkylation was achieved with methyl Grignard. (PNP)HfMe3 and (PNP)Hf(CH2SiMe3)2Cl displayed remarkably irregular coordination environments about hafnium, in contrast to the approximately octahedral structure of (PNP)HfCl3. (PNP)HfMe3 was found to be thermally stable at 75 degrees C, whereas thermolysis of (PNP)Hf(CH2SiMe3)2Cl under similar conditions led to a mixture of products. The major decomposition product is believed to be a Hf alkylidene complex on the basis of in situ NMR spectroscopic observations (e.g., delta 248.2 ppm in the 13C{1H} NMR spectrum). The reaction of (PNP)TaF4 with an excess of ethyl Grignard led primarily to the double alkylation product, (PNP)Ta(CH2CH3)2F2. Repeating this reaction in the presence of excess ethyl Grignard and dioxane resulted in the formation of an ethylene complex, (PNP)Ta(=CHCH3)(C2H4). In Chapter III, a C-C reductive elimination study is described comparing two pincer ligand scaffolds: Me(PNP) ligand and TH(PNP) ligand. The tied ligand has previously been found to be more sterically demanding than the untied ligand, which has allowed for faster N-C cleavage, faster oxidative addition and a more selective alkyne dimerization catalyst. This study reveals that the tied ligand complex, TH(PNP)Rh(C6H4CF3)(Ph), undergoes slower reductive elimination of p-Ph-C6H4CF3 (< 4% after 7 h at 38 degrees C; t1/2 = 7.7 h at 64 degrees C; t1/2 = 2.13 h at 75 degrees C) than Me(PNP)Rh(C6H4CF3)(Ph) (t1/2 = 15.6 min at 38 degrees C). Reductive Elimination C-C X-ray crystallography Metal alkyl Alkylidene Rhodium Tantalum Hafnium Pincer
6	Synthesis and Photochemical Properties of Poly(phenylenevinylene)s with Highly Regulated Structures / 高度に構造制御されたポリ(フェニレンビニレン)の合成および光化学的性質 / コウドニコウゾウセイギョサレタポリ ( フェニレンビニレン ) ノゴウセイオヨビコウカガクテキセイシツ Wakioka, Masayuki 24 September 2009 (has links) Kyoto University (京都大学) / 0048 / 新制・課程博士 / 博士(工学) / 甲第14942号 / 工博第3169号 / 新制\|\|工\|\|1475(附属図書館) / 27380 / UT51-2009-M856 / 京都大学大学院工学研究科物質エネルギー化学専攻 / (主査)教授小澤文幸, 教授大江浩一, 教授中村正治 / 学位規則第4条第1項該当 Poly(phenylenevinylene) Streocontrolled Synthesis Photoisomerization Palladium Complex Polycondensation Cross-Couling Homo-Coupling Reductive Elimination 500
7	Strong Bond Activation with Late Transition-Metal Pincer Complexes as a Foundation for Potential Catalysis Zhu, Yanjun 2012 May 1900 (has links) Strong bond activation mediated by pincer ligated transiton-metal complexes has been the subject of intense study in recent years, due to its potential involvement in catalytic transformations. This dissertation has focused on the net heterolytic cleavage of B-H and B-B bonds across the N-Pd bond in a cationic (PNP)Pd fragment, the C-H oxidative addition to a (PNP)Ir center and the recent results on the C-H and C-O oxidative addition in reactions of aryl carboxylates with the (PNP)Rh fragment. Transition metal carbene and carbyne complexes are of great interest because of their role in a wide variety of catalytic reactions. Our work has resulted in the isolation of a rhodium(I) difluorocarbene. Reaction of the rhodium difluorocarbene complex with a silylium salt led to the C-F bond cleavage and the formation of a terminal fluorocarbyne complex. Reductive elimination is a critical step of cross coupling reactions. In order to examine the effect of the pincer ligand on the reductive elimination reactions from Rh(III), the first pi-accepting PNP ligand bearing pyrrolyl substituents was prepared and installed onto the rhodium center. Arylhalide (halide = Br, I) oxidative addition was achieved in the presence of donor ligands such as acetonitrile to form stable six-coordinate Rh(III) compounds. The C-O reductive elimination reactions in this system were also explored. bond activation transition-metal complxes C-H activation C-O activation oxidative addition reductive elimination fluorocarbyne complex
8	Synthesis and reactivity of [RhI(CO)2(L)] and [RL][RhI2(CO)2] rhodium complexes where L is a nitrogen-containing ligand for the methanol carbonylation reaction / Synthèse et réactivité des complexes rodhium neutres [RhI(CO)2(L)] et anioniques [RL][RhI2(CO)2] (R=H ou Me) comportant des ligands azotés L : étude du mécanisme catalytique de la réaction de carbonylation du méthanol Adcock, Romain 10 November 2011 (has links) Ce travail est centré sur la synthèse de complexes du rhodium contenant un ligand azoté et leur mise en œuvre dans la réaction catalytique de carbonylation du méthanol en acide acétique. Dans une première partie, nous nous intéressons à la préparation de complexes neutres de formule générale [RhI2(CO)(L)] (L = amines, imidazoles et pyrazoles) et à quelques homologues chlorés. Ces complexes plans carrés manifestent une réactivité directement liée à l’encombrement stérique du ligand azoté L dans la réaction d’addition oxydante de l’iodomethane suivie de la cis-migration du groupement méthyle pour former l’espèce acétyle. Dans une deuxième partie, les complexes précédents ont été engagés dans des essais catalytiques de carbonylation du méthanol dans les conditions du procédé industriel. Comme il s’est avéré que les complexes neutres se transforment en espèce [RhI2(CO)2]- pour laquelle les contre-cations associés sont constitués du ligand azoté protoné ou methylé, nous avons effectué la préparation et la caractérisation des complexes [HNR3][RhI2(CO)2] ou [MeNR3][RhI2(CO)2]. Par IR, RMN et électrochimie, nous nous sommes intéressés aux phénomènes d’appariement d’ions et nous montrons qu’il s’agit dans le meilleur des cas d’interactions hydrogènes. Celles-ci influent la vitesse de la réaction oxydante de CH3I. Dans la dernière partie, nous avons complété une étude, précédemment initiée au laboratoire, sur le mécanisme, qui dans la dernière étape du cycle catalytique permet de passer de l’espèce acétyle [RhI3(COCH3)(CO)2]- à l’espèce active [RhI2(CO)2]- avec production de l’iodure d’acyle. A l’inverse du concept admis d’élimination réductrice de CH3COI suivie de son hydrolyse immédiate en CH3COOH et HI, nous montrons, avec l’appui de calculs théoriques (DFT) qu’en fait un ligand I- est substitué par un ligand acetate pour conduire à l’espèce [RhI2(OAc)(COCH3)(CO)2]-. L’élimination réductrice produit alors l’anhydride acétique qui est hydrolysé en CH3COOH régénérant [RhI2(CO)2]-. Un tel mécanisme opère en présence d’ions acetate dans les milieux faiblement hydratés visés par l’industriel. / This study focuses on the synthesis and reactivity of rhodium complexes bearing N- containing ligands or counter-cations for the [Rh]-catalyzed methanol carbonylation reaction to produce acetic acid under the industrial Celanese Acid Optimization (AO) process conditions. In a first part, full synthesis and characterization of neutral Rh(I) square planar cis- [RhX(CO)2(L)] (X = Cl or I) complexes have been described, for which L is an N-ligand belonging to the amine, imidazole or pyrazole family. For the [RhI(CO)2(L)] complexes, variable-temperature 13C{1H} NMR spectroscopy has put in evidence a fluxional behavior for the different sized L ligands involved. The rate of this fluxional process reveals to be related to both electronic and steric contributions brought by L to the Rh center. These parameters (mainly steric), supported by single-crystal X-ray analyses in the solid state, also influence significantly the kinetics of the methyl iodide oxidative addition reaction followed by rapid CO migratory insertion, the overall being the rate determining step of the [Rh]-catalyzed methanol carbonylation cycle. In absence of CO, this reaction gives rise to the corresponding neutral Rh(III) acetyl complex, which immediately dimerizes to afford [Rh(μ- I)I(COMe)(CO)(L)]2 complex, for which several X-ray crystal structures have been obtained and studied. In addition, the surprising C-H activation in the case of a tBu-pyrazole ligand giving rise to a cyclometalated Rh dimer is reported. In a second part, the reactivity of the latter neutral Rh(I) [RhI(CO)2(L)] complexes as potential precursors has been investigated by batch experiments for the methanol carbonylation reaction. Mechanistic understanding via VT-HP-NMR experiments enabled to detect mainly anionic Rh(I) [RL][RhI2(CO)2] (R = H or CH3 according to the working conditions) complexes formed by decoordination followed by quaternization of the L ligand. Despite this result, the pyrazole family ligands showed better stability under the harsh process conditions. Thus, it cannot be ruled out that equilibrium between neutral and anionic species co-exist in the reaction medium at high temperatures and that [RL]I salt dissociation occurs, restoring the L ligand into the Rh coordination sphere. At this stage we focused on the anionic Rh(I) complex and prepared a series of [XNR3][RhI2(CO)2] (X = H or CH3) species, which have been fully characterized. Infrared, NMR, conductivity experiments and DFT model calculations together put in evidence ion interactions according to the nature of the ammonium counter-cation. Protonated cations significantly impact on the kinetics of the methyl iodide oxidative addition presumably due to H-interactions with the Rh square plane. The final part deals with the mechanism of the reductive elimination reaction, the last step of the [Rh]-catalyzed methanol carbonylation cycle, which from complex [RhI3(COCH3)(CO)2]-, regenerates [RhI2(CO)2]-. In contrast to the classically admitted mechanism of reductive elimination of CH3COI followed by subsequent hydrolysis to form AcOH and HI, we demonstrate from experimental DFT calculation that substitution of an iodo ligand by an acetate ion occurs to give rise to the [RhI2(OAc)(COCH3)(CO)2]- species. Thus, reductive elimination regenerates [RhI2(CO)2]- and produces acetic anhydride, which after hydrolysis affords two molecules of acetic acid. Such a mechanism operates under process conditions at low water content with a significant amount of acetate ions. Ligands azotés Rhodium Carbonylation du méthanol Addition oxydante Elimination réductrice Mécanisme réactionnel N-ligand (amine, imidazole, pyrazole) Rhodium Methanol carbonylation MeI oxidative addition Reductive elimination Reaction mechanism C-H activation
9	Complexes NCN de Ni(II) et Ni(III) : synthèse, caractérisation et rôle dans le mécanisme de couplage C-O, C-N et C-halogènes Cloutier, Jean-Philippe 09 1900 (has links) No description available. Complexes pinces Ni(II) Ni(III) Ni(IV) NCN Nickel Couplage C-O Couplage C-N Couplage C-halogènes Élimination réductrice Comproportionation Disproportionation Pincer complexes High-valent NCN pincer complexes Functionalization C-O coupling C-N coupling C-halogen coupling Reductive elimination C-H activation DFT
10	Reactivity of well-defined organometallic copper(III) complexes in carbon-heteroatom bond forming reactions Casitas Montero, Alícia 01 June 2012 (has links) This thesis is focused on the unexplored field of organometallic copper(III) chemistry. Arylcopper(III) complexes have been proposed as key intermediates in Ullmann condensation reactions that consist in the coupling of aryl halides and heteroatom nucleophiles catalyzed by copper. The study of the reactivity of well-defined arylcopper(III) complexes may provide a better understanding of the mechanism of Ullmann condensation reactions, which is still under intense debate. In this doctoral dissertation we study the feasibility of well-defined arylcopper(III) complexes, which are stabilized within macrocyclic ligands, to participate in C-heteroatom bond forming reactions. We develop copper-catalyzed C-N and C-O bond forming reactions, as well halide exchange reactions, including fluorinations, based on Cu(I)/Cu(III) catalytic cycle within model aryl halide substrates. We uncover the fundamental understanding of the two-electron redox steps, oxidative addition and reductive elimination, at copper. / Aquesta tesi es centra en el camp de la química organometàl•lica del coure(III) que roman sense explorar. Els complexos arilcoure(III) s'han proposat com a intermedis clau en les reaccions de condensació Ullmann que consisteixen en l'acoblament d'halurs d'arils i nucleòfils basats en heteroàtoms catalitzades amb coure. L'estudi de la reactivitat de complexos arilcoure(III) ben definits pot proporcionar una millor comprensió del mecanisme de les reaccions de condensació Ullmann, el qual es troba sota un intens debat. En aquesta tesi doctoral s'estudia la viabilitat del complexos arilcoure(III), estabilitzats en lligands macrocíclics, de participar en reaccions de formació d'enllaç carboni-heteroàtom. S'han desenvolupat reaccions de formació d'enllaç C-N i C-O així com reaccions d'intercanvi d'halurs, on s'inclouen fluoracions, catalitzades amb coure i basades en un cicle catalític Cu(I)/Cu(III) utilitzant substrats models d'halur d'aril. S'ha obtingut una comprensió fonamental de les etapes redox a dos electrons, addició oxidant i eliminació reductiva, en coure. Reductive elimination Eliminació reductiva Eliminación reductiva Organometallic copper(III) Coure(III) organometàl·lic Cobre(III) organometálico Carbon-heteroatom bond Enllaç carboni-heteroàtom Enlace carbono-heteroátomo Copper catalysis Catàlisi amb coure Catálisis con cobre Fluorination Fluoració Fluoración Oxidative addition Addició oxidant Adición oxidante 547

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