Global ETD Search

51	Novel chiral wide bite angle ligands for asymmetric catalysis Czauderna, Christine F. January 2013 (has links) Achiral wide bite angle ligands have been shown to be highly active and to induce excellent chemo- and regioselectivities in many homogeneously catalyzed reactions. However, only a few examples of chiral wide bite angle ligands are known so far. A diphenyl ether backbone was selected to allow maximum synthetic versatility and potential for a modular approach to design and synthesize such chiral diphosphorus ligands. Three synthetic strategies have been explored in this thesis: i) introduction of chiral substituents in the ligand backbone, ii) the use of P-stereogenic donor atoms and iii) the synthesis of chiral mixed-donor ligands bearing chiral auxiliary groups on the phosphorus atoms. Functionalization of the 3,3'-positions of 2,2'-bis(diphenylphosphino)diphenyl ether by carboxylic acid or ether auxiliaries was achieved via straightforward four-step routes to generate a library of ligands that were tested in various catalytic reactions. In the Pd-catalyzed asymmetric allylic alkylation of l,3-diphenyl-2-propenyl acetate and cyclohexyl-2-enyl acetate with dimethyl malonate the enantioselectivity was found to depend on the size of the chiral auxiliary introduced within the diphenyl ether backbone and its proximity to the phosphorus donor groups and hence to the active metal centre. Two types of mixed donor bidentate diphosphorus ligands based on the diphenylether backbone have been established, i.e. phosphine-phosphite and phosphine-phosphonite derivatives. A small ligand library bearing different chiral auxiliaries was accomplished via straightforward syntheses that enable derivatization of the respective phosphite and phosphonite moieties in the final step. In the Rh-catalysed hydrogenation of several benchmark substrates high conversion and moderate to high enantioselectivities (up to 97% for dimethyl itaconate) were obtained. The enantioselectivity was influenced by the size of the ortho-substituent on the chiral auxiliary group of the phosphite or phosphonite fragment. Two modular synthetic approaches for the preparation of novel wide bite angle diphosphine ligands containing stereogenic P-atoms have been developed. Both protocols involved diphenylether as backbone and the chiral ephedrine based precursor (2R[subscript(P)],4S[subscript(C)],5R[subscript(C)])-oxazaphospholidine borane as initial auxiliary to induce chirality at phosphorus. Various novel diphosphines were isolated as highly enantioenriched compounds with dr-ratios up to 95:5. 541.2242
52	Continuous flow homogeneous catalysis using ionic liquid/supercritical fluid biphasic systems Martins, Tânia Isabel Quintas January 2010 (has links) Ionic liquid/scCO₂ biphasic systems have been studied as a possible solution to the main problems concerning homogeneous catalysis reactions such as, the product/catalyst separation, the catalyst retention in the reaction medium and the use of organic solvents. The hydroformylation of long chain alkenes (1-octene) has been carried out as a continuous flow reaction using [OctMIM]Tf₂N (OctMIM = 1-octyl-3-methylimidazolium, Tf = CF₃SO₂) as the reaction solvent and scCO₂as the mobile phase to extract the products. The performance of the rhodium complexes formed with the ionic ligands [PentMIM][TPPTS] (1-pentyl-3- methylimidazolium tri(m-sulfonyl)triphenylphosphine) and [OctMIM][TPPTS] (1-octyl-3- methylimidazolium tri(m-sulfonyl)triphenylphosphine) is described under different sets of experimental conditions. Continuous flow hydroformylation of 1-octene was also carried out using a SILP (Supported Ionic Liquid Phase) catalyst formed with the TPPTS-based ionic ligands named above. The SILP system described in this work has the peculiarity of introducing the “without gases” approach: syn gas was synthesised in situ by the decomposition of formaldehyde. The performance of both systems is compared in the end. The extension of the continuous flow ionic liquid/scCO₂ biphasic system is shown with the optimisation of the silver-catalysed heterocyclisation of furans. A comparison is carried out with a previously developed and optimised continuous flow heterogeneous system. 541.39
53	Elaboration de ligands bidentates supramoléculaires par auto-assemblage d'aminocyclodextrines et de phosphines hydrosolubles - application à la catalyse en milieu aqueux. / Elaboration of cyclodextrin-based supramolecular hydrosoluble PN heterobidentate ligands for aqueous catalysis Patrigeon, Julien 01 July 2010 (has links) Des ligands supramoléculaires bidentates P,N hydrosolubles ont été élaborés parauto-assemblage de différentes mono-amino-β-cyclodextrines et d'une phosphinehydrosoluble appropriée. La capacité de ces super-structures à coordiner un métal aété évaluée sur le platine et le rhodium. Les complexes organométalliques ainsiformés ont été totalement caractérisés par spectroscopie RMN.Les tests en hydroformylation en milieu aqueux ont permis de montrer l'efficacitéde tels systèmes, aussi bien en termes de sélectivité qu'en termes d'activité. / Supramolecular PN heterobidentate ligands have been elaborated by self-assembling mono-amino-β-cyclodextrins with an appropriate water-soluble phosphine. Their coordination ability has been evaluated on platinum and rhodium complexes and completely characterized by NMR spectroscopy. Catalysts have then been tested in rhodium-catalyzed hydroformylation in aqueous media. Results proved that such ligands exhibit similar behavior than molecular one. Catalyse supramoléculaire Cyclodextrine Auto-assemblage Rhodium Platine Hydroformylation Catalyse en milieu aqueux Spectroscopie RMN
54	Oligonucleotide based ligands in homogeneous transition metal catalysis Eichelsheim, Tanja January 2012 (has links) Catalysis plays an important part in our society. Numerous transition metal catalysts have been developed which can convert many different substrates in a wide range of reactions. Catalysis also plays an important role in nature and therefore special catalysts, enzymes, have evolved over time. Enzymes are tremendously efficient giving high yields and selectivities both regio and chemical but have a limited substrate and reaction scope. It was speculated that by combining the two, an ideal catalyst can be obtained. We planned to achieve this by introducing a transition metal, the catalytic centre, into the chiral environment of a double helical oligonucleotide. The transition metals were introduced by coordinating them to a ligand which was located in the chiral environment of a double helix. The ligand was either covalently bound (Chapter 2) or non-covalently bound (Chapter 3) to the oligonucleotide (Figure 1). Figure 1: A) covalent introduction of a transition metal into a nucleotide B) non-covalent introduction of a transition metal into a nucleotide For the covalent approach a phosphine ligand was chosen. A nucleoside was modified with an alkyne to which a phosphine moiety could be coupled via the copper catalysed 1,3-dipolar cycloaddition. The modified nucleoside was incorporated into an oligonucleotide before attempting to attach the phosphine moiety. The monomer was used as a ligand in allylic substitution and hydroformylation. In the non-covalent approach polyamide minor groove binders were functionalised with an amine linker. Phosphine moieties were connected via amide bond formation. Although the coupling worked effortlessly the phosphines oxidised during purification therefore dienes were also investigated. 600
55	Nanopartículas de Ródio: componentes para a preparação de catalisadores para reações de hidroformilação de olefinas / Rhodium Nanoparticles: components for the preparation of catalysts for hydroformylation Garcia, Marco Aurélio Suller 12 August 2016 (has links) A importância que a catálise representa para a sociedade pode ser vista em números: 90% dos processos da indústria química e mais de 20% de todos os produtos industriais comercializados no mundo utilizam uma ou mais etapas catalíticas. Assim, desenvolver catalisadores eficientes, ativos e seletivos é a solução para criar tecnologias mais limpas e sustentáveis. Além disso, reações químicas que geram novas ligações C-C estão entre as transformações mais relevantes na química orgânica e são a base desse trabalho. Os catalisadores de ródio apresentados aqui fazem parte de um trabalho minucioso de desenvolvimento, síntese e caracterização de nanopartículas e suportes magnéticos funcionais que foram utilizados em transformações de diversas moléculas. O estudo inicial com nanopartículas de ródio suportadas, em reações de hidrogenação do cicloexeno, serviu para a compreensão de como se comportam essas nanoestruturas e da influência que diferentes ligantes orgânicos e estabilizantes podem ter em uma aplicação catalítica bastante conhecida. O sistema catalítico mostrou-se bastante ativo e reutilizável,despertando o nosso interesse ao seu aperfeiçoamento para aplicação em reações de hidroformilação. Antes da síntese de catalisadores suportados, estudos com nanopartículasnão-suportadas mostraram que um sistema modificado pela adição de fosfinas era necessário para ativação do catalisador e que o estabilizante utilizado afetava a atividade catalítica. Assim, para possibilitar o ancoramento eficiente das espécies ativas, uma modificação da superfície do suporte magnético com a metildifenilfosfina foi realizada. A fosfina funcionalizada sobre o suporte viabilizou sua interação com as espécies ativas e evitou a sua lixiviação, possibilitando o reuso do catalisador. A reação de hidroformilação do oct-1-eno atingiu 96% de conversão e 82% de seletividade para aldeídos, em 6 horas a 80°C. A carga metálica do catalisador foi de apenas 0,2%. Buscando aumentar a eficiência na etapa de imobilização do metal e uma melhor atividade catalítica que possibilitasse o uso de substratos mais complexos, o suporte magnético foi modificado com um polímero hiper-ramificado. Essa modificação possibilitou aumentar a quantidade de grupos fosfinas sobre o suporte, assim como levou a um significativo aumento na carga de metal. A reação de hidroformilação de produtos naturais foi possível e, com o composto estragol, conversões de 100% foram alcançadas em 6 horas, com seletividade de 70% para aldeídos. Mesmo com evidências que sugerem a formação de espécies ativas moleculares, o suporte modificado possibilitou que o catalisador mantivesse sua atividade e seletividade por pelo menos seis reações sucessivas. Os materiais desenvolvidos apresentaram estabilidade quando manuseados ao ar, sem prejudicar sua vida útil e fácil separação. / The importance of catalysis to society may be seen in numbers: 90% of chemical production processes and more than 20% of all industrial products sold in the world use one or more catalytic steps. Thus, the development of efficient, active, and selective catalysts is crucial for creating cleaner and sustainable technologies. In addition, chemical reactions that generate new C-C bonds are among the most important transformations in organic chemistry and are the basis of this work. Rhodium catalysts presented herein are part of a careful investigation, which included the development, synthesis and characterization of metal nanoparticles and magnetic functional supports for use in the transformation of various molecules. The initial study of supported rhodium nanoparticles in cyclohexene hydrogenation reactions has driven our understanding of the behavior of these nanostructures, and the influence that different ligands and stabilizers may have in a well-known catalytic application. The identification of a highly active and recyclable catalytic system aroused our interest for its improvement for application in hydroformylation reactions. Prior to the synthesis of supported catalysts, studies with non-supported nanoparticles revealed that a modified system with the addition of phosphines was required for activation of the catalyst and the stabilizer used affected the catalytic activity. Thus, to enable efficient immobilization of the active species, the surface of the magnetic support was modified with methyldiphenylphosphine. The catalyst preparation removed, at least partially, the stabilizer adsorbed on the nanoparticles surfaces. The phosphine-functionalized support anchored the active species and avoided their leaching, allowing the reuse of the catalyst. The hydroformylation reaction of oct-1-ene reached 96% of conversion and 82% of selectivity to aldehydes, in 6 hours at 80°C. The metal loading of the catalyst was only 0.2%. Seeking to increase the efficiency in metal immobilization step and a better catalytic activity that would enable the use of more complex substrates, the magnetic support was modified with a hyperbranched polymer, which allowed an increase in the amount of external phosphines, as well as a significant increase in metal loading on the support. The hydroformylation reaction of natural products was possible and, with the estragole compound, 100% of conversion was achieved in 6 hours with 70% of selectivity to aldehydes. Despite evidence that suggests the formation of active molecular species, the modified support has enabled the catalyst to retain its activity and selectivity for at least six successive reactions. The materials developed could be handled in air without damaging their catalytic activity, durability and separation properties. Aldehydes Aldeídos alkenes Alquenos Funcionalização Functionalization Hidroformilação Hydroformylation Magnetic support Nanopartículas de ródio Rhodium nanoparticles Suporte magnético
56	The Use of Reversible Covalent Bonding and Induced Intramolecularity to Achieve Selectivity and Rate Acceleration in Organic Reactions Worthy, Amanda D. January 2013 (has links) Thesis advisor: Kian L. Tan / Chapter 1. Catalytic directing group, I, which was designed with the ability to form a reversible covalent bond with a substrate and bind a metal, was shown to direct the hydroformylation of allylic amines. The efficient regioselective hydroformylation of a variety of 1,2-disubstituted allylic sulfonamides to form β-amino-aldehydes under mild conditions has been shown. Chapter 2. Building off of the successful application of I, enantioenriched catalytic directing group, II, was designed and synthesized. It retained the essential features to direct hydroformylation to obtain good regioselectivity while also providing a chiral environment to induce absolute stereocontrol. Under mild conditions, a variety of disubstituted olefins react to give good yields and excellent enantioselectivites. Thus, the first enantioselective reaction performed with a catalytic directing group was demonstrated. Chapter 3. A new set of organocatalysts was developed that benefits from reversible covalent bonding and induced intramolecularity. The desymmetrization of meso-1,2-diols was accomplished using organocatalyst III, which was synthesized easily and cheaply. Experimental results indicate that the selectivity and increased reactivity are a result of the ability of III to pre-organize the substrate through a reversible, covalent bond. A variety of cyclic and acylic substrates were shown to react efficiently with good enantioselectivities under mild conditions. The catalyst's ability to functionalize cis-1,2-diols selectively indicated it might be successfully applied to site selective catalysis. Thus, the selective functionalization of a secondary alcohol in the presence of a primary alcohol was developed using a combination of binding selectivity and stereoselectivity. The (S)-enantiomer forms the secondary functionalized product while the (R)-enantiomer forms the primary functionalized product with high selectivity. As the enantiomers preferentially form different functionalized products, a regiodivergent reaction on a racemic mixture resulted giving two valuable enriched products. / Thesis (PhD) — Boston College, 2013. / Submitted to: Boston College. Graduate School of Arts and Sciences. / Discipline: Chemistry. catalysis hydroformylation induced intramolecularity reversible covalent bonding silylation site selective functionalization
57	Synthesis of amino acids by metal-catalysed reactions Teoh, Euneace Ching Mei January 2004 (has links) Abstract not available Amino acids -- Synthesis Organic cyclic compounds -- Synthesis Hydroformylation Hydrogenation Metal catalysts Asymmetric synthesis Enantioselective catalysis
58	Characterization and Reaction Studies of Silica Supported Platinum and Rhodium Model Catalysts Lundwall, Matthew James 2010 December 1900 (has links) The physical and catalytic properties of silica supported platinum or rhodium model catalysts are studied under both ultra high vacuum (UHV) and elevated pressure reaction conditions (>1torr). Platinum or rhodium nanoparticles are vapor deposited onto a SiO2/Mo(112) surface and characterized using various surface analytical methods. CO chemisorption is utilized as a surface probe to estimate the concentration of various sites on the nanoparticles through thermal desorption spectroscopy (TDS) and infrared reflection absorption spectroscopy (IRAS) along with microscopy techniques to estimate particle size. The results are compared with hard sphere models of face centered cubic metals described as truncated cubo-octahedron. Results demonstrate the excellent agreement between chemisorption and hard sphere models in estimating the concentration of undercoordinated atoms on the nanoparticle surface. Surfaces are then subjected to high pressure reaction conditions to test the efficacy of utilizing the rate of a chemical reaction to obtain structural information about the surface. The surfaces are translated in-situ to a high pressure reaction cell where both structure insensitive and sensitive reactions are performed. Structure insensitive reactions (e.g. CO oxidation) allow a method to calculate the total active area on a per atom basis for silica supported platinum and rhodium model catalysts under reaction conditions. While structure sensitive reactions allow an estimate of the types of reaction sites, such as step sites (≤C7) under reaction conditions (e.g. n-heptane dehydrocyclization). High pressure structure sensitive reactions (e.g. ethylene hydroformylation) are also shown to drastically alter the morphology of the surface by dispersing nanoparticles leading to inhibition of catalytic pathways. Moreover, the relationships between high index single crystals, oxide supported nanoparticles, and high surface area technical catalysts are established. Overall, the results demonstrate the utility of model catalysts in understanding the structure-activity relationships in heterogeneous catalytic reactions and the usefulness of high pressure reactions as an analytical probe of surface morphology. Platinum Rhodium Model Catalysts nanoparticles ethylene carbon monoxide CO oxidation hydroformylation dehydrocyclization
59	1,3- DIPHOSPHITE LIGANDS WITH FURANOSIDE BACKBONE: A POWERFUL TOOL IN ASYMMETRIC CATALYSIS Gual Gozalbo, Aitor 09 June 2009 (has links) La catàlisi asimètrica es part de la síntesi asimètrica i fa possible la transformació de substrats pro-quirals o racèmics en productes quirals emprant quantitats catalítiques de compostos que contenen informació quiral. El disseny de nous lligands es l'etapa clau per a obtenir alts nivells de reactivitat i selectivitat. Els carbohidrats son uns dels membres més importants dintre de la "chiral pool".Aquesta tesi esta enfocada en el desenvolupament i aplicació en catàlisi asimètrica de nous lligands amb esquelet carbohidrat.Aquestos lligands foren aplicats amb èxit a la hidroformilació asimètrica catalitzada per Rh d'alquens monosubstituïts, interns disubstituïts i 1,1´-disubstituïts.L'efecte de les modificacions estructurals dels lligands 1,3-difosfit sobre els resultats catalítics a l'alquilació al·lílica catalitzada per Pd de compostos fenil-al·lílics ha sigut també estudiat en aquesta tesis. Finalment, els lligands 1,3-difosfit han sigut aplicats a l'estabilització de nanopartícules metàl·liques, i la seva aplicació a la hidrogenació de o- i m-metilanisol. / Asymmetric catalysis is part of the asymmetric synthesis and makes possible the transformation of a pro-chiral or racemic substrate into a chiral product using catalytic amounts of the compounds which contain the chiral information. The design of new ligands is perhaps the most crucial step to achieve the highest levels of reactivity and selectivity. Carbohydrates are the most prominent members of the "chiral pool".This thesis focus on the development and application in asymmetric catalysis of new 1,3-diphosphite with carbohydrate backbone. These ligands were successful applied in the Rh-asymmetric hydroformylation of monosubstituted, disubstituted internal and 1,1´-disubstituted alkenes.The effect of the structural modification of these 1,3-diphosphite ligands on the catalytic results of the Pd-allylic alkylation of phenyl-allyl compounds was also studied in this thesis. Finally, the 1,3-diphosphites ligands were applied to stabilize metal nanoparticles. These nanocatalysts were tested in the hydrogenation of pro-chiral o- and m-methylanisole. Carhydrates diphosphites nanoparticles asymmetric hydroformylation allylic alkylation hydrogenation 54 542 546 547
60	Transition metal complexes of bis(phosphorus) donor ligands derived from multifunctional diols synthesis, isomerization, cation binding, and catalysis / Owens, Samuel Britt. January 2008 (has links) (PDF) Thesis (Ph. D.)--University of Alabama at Birmingham, 2008. / Additional advisors: Houston Byrd, Chris Lawson, Sadanandan Velu, Charles Watkins. Description based on contents viewed Feb. 9, 2009; title from PDF t.p. Includes bibliographical references.

Search results