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391	PREPARATION AND APPLICATION OF CATALYSTS FOR THE STEREOSPECIFIC REDUCTION AND PHOTOOXYGENATION OF OLEFINS IN CONTINUOUS OPERATIONS: A NOVEL METHOD FOR THE PRODUCTION OF ARTEMISININ Fisher, Daniel C 01 January 2017 (has links) Over the last two centuries, the discovery and application of catalysts has had a substantial impact on how and what chemicals are produced.Given their broad significance, our group has focused on developing new catalyst systems that are recoverable and reusable, in an attempt to reduce concomitant costs. Our efforts have centered on constructing a recyclable chiral heterogeneous catalyst capable of effecting asymmetric hydrogenations of olefins with high stereoselectivity. A class of phosphinoimidazoline ligands, developed by researchers at Boehringer-Ingelheim, known as BIPI ligands, have proven efficacious in the asymmetric reduction of alkenes. However, these chiral ligands are homogeneous and coordinated to precious metals, rendering them irrecoverable and expensive. To address these issues, our group has derivatized the BIPI ligand-metal complex and immobilized it to the surface of graphene oxide as well as polystyrene. Their efficacy and recyclability toward the asymmetric hydrogenation of a functionalized olefin have been evaluated. Another facet of our work has included developing a cost effective synthetic process to artemisinin, the gold standard drug in the treatment of malaria.As a natural product, artemisinin’s worldwide supply remains highly unpredictable, contributing to great price volatility.Combining the benefits of catalysis and the advantages of continuous flow chemistry, our research has sought to develop an economical approach to convert a biosynthetic precursor, artemisinic acid, to artemisinin in three chemical transformations. High-throughput experimentation allowed us to screen a prodigious number of catalysts and identify those effective in the asymmetric hydrogenation artemisinic acid to dihydroartemisinic acid, the first step in the transformation. This screening directed us to an inexpensive, heterogeneous ruthenium catalyst. The second step of the process includes the photooxygenation of dihydroartemisinic acid, which involves photochemically generated singlet oxygen. We have evaluated a commercially available heterogeneous photocatalyst packed in a transparent bed, surrounded by light emitting diodes in the continuous photooxygenation of dihydroartemisinic acid to dihydroartemisinic acid hydroperoxide. The third and final step, an acid induced hock cleavage, initiates an intricate cascading reaction that installs an endoperoxide bridge to deliver artemisinin. Our process afforded a 57% yield from dihydroartemisinic acid to artemisinin. Artemisinin asymmetric hydrogenation photooxygenation heterogeneous catalysis rose bengal on polystyrene continuous flow chemistry Catalysis and Reaction Engineering Organic Chemistry
392	Préparation de tensioactifs par aldolisation de cétoses non protégés / Aldolisation of unprotected ketoses to surfactants Zhu, Biwen 20 September 2018 (has links) Dans ce manuscrit, une voie atome économique d'un robuste amphiphile polyols à base de alkyle chaîne liée à liaison C-C ont été développés, ce qui est plus stable pour des applications plus larges. Ce processus implique l'utilisation de matières premières renouvelables et relativement peu coûteuses. Des cétoses tels que la 1,3-dihydroxyacétone et le D-fructose ont été utilisés comme substrats avec des aldéhydes comme agents d'alkylation sans aucune étape de protection-déprotection. La synthèse a été divisée en deux étapes, dans la première étape, les cétoses déprotonées réagissent avec les électrophiles aldéhydes pour former les intermédiaires hydroxycétones. Ensuite, une seconde étape d'hydrogénation avec un catalyseur du ruthénium sur alumine sous pression d'hydrogène a donné accès aux polyols alkylés. Le rendement global de ce procédé en deux étapes est modéré compte tenu de la difficulté de faire réagir une partie fortement hydrophobe avec une partie fortement hydrophile. Ensuite, ces adduits de tétraols obtenus avec la 1,3-dihydroxyacétone ont également été évalués en tant que tensioactifs en effectuant des tests physico-chimiques (CMC, point Krafft et Phase Inverse Temperature). Les résultats ont montré que ces nouveaux agents tensioactifs liés à la liaison C-C sont aussi efficaces que d'autres agents tensioactifs disponibles dans le commerce en diminuant la tension de surface, ce qui est une propriété très attrayante pour des applications potentielles / In this manuscript, an atom economic route of C-C bond based surfactants has been developed. They are more stable for broader applications. This process involves the use of renewable and relatively low cost raw materials. Ketoses such as 1,3-dihydroxyacetone and D-fructose were used as substrates with aldehydes as alkylation agents without any protection-deprotection step. The synthesis has been divided into two steps, in the first step the deprotonated ketoses react with the aldehydes electrophiles to form the hydroxyketone intermediates. Then, a second step of hydrogenation with Ruthenium on alumina catalyst under hydrogen pressure gave access to the alkylated polyols. The overall yield of this two-step process is moderate considering the difficulty of reacting a highly hydrophobic part with a highly hydrophilic part. Then these tetraols adducts obtained with 1,3-dihydrdoxyacetone were also evaluated as surfactants by making physico-chemical tests (CMC, Krafft point and Phase Inverse Temperature). Results have exhibited this novel C-C bond connected surfactants perform as efficient as other commercially available surfactants in decreasing the surface tension which is a very attractive property for potential applications Aldolisation Formation de liaisons C-C Cétoses Hydrogénation Tensioactifs Aldolisation C-C bond forming Ketoses Hydrogenation Surfactants 540
393	Concerted or Stepwise? : <i>β-Elimination, Nucleophilic Substitution, Copper Catalysed Aziridination and Ruthenium Catalysed Transfer Hydrogenation Studied by Kinetic Isotope Effects and Linear Free-Energy Relationships</i> Ryberg, Per January 2002 (has links) <p>This thesis describes the use of kinetic isotope effects, linear free energy relationships and stereochamical studies to distinguish between different mechanistic alternatives and to obtain information about transition state structure.</p><p>In the first part fluorine and deuterium kinetic isotope effects were determined for the base promoted HF elimination from 4-fluoro-4-(4’-nitrophenyl)butane-2-on. During this work a new method for the determination of fluorine kinetic isotope effects was developed. The results from the study demonstrates that the reaction proceeds via an E1cB<sub>ip</sub> mechanism.</p><p>In the second part the transition state structure for the S<sub>N</sub>2 reaction between ethyl chloride and cyanide ion in DMSO was studied. Kinetic isotope effects for six different positions in the reacting system, both in cyanide and ethyl chloride, were determined. The experimental isotope effects were then compared with the theoretically predicted isotope effects. </p><p>The third part describes the use of Hammett type free-energy relationships and stereochemical evidence to study the mechanism of the copper catalysed alkene aziridination. The results from the study support a model that involves the simultaneous presence of two different copper nitrene intermediates. One which reacts non-stereospecifically via a radical intermediate and one which reacts stereospecifically via a concerted mechanism.</p><p>In the fourth part a mechanistic study of the Ru(aminoalcohol) catalysed transfer hydrogenation of acetophenone in isopropanol is described. Kinetic isotope effects were determined for both proton and hydride transfer. The observation of significant primary deuterium kinetic isotope effects for both proton and hydride transfer support a mechanism where the proton and hydride are transferred simultaneously in a concerted mechanism.</p> Organic chemistry Kinetic isotope effect linear free energy relationship elimination substitution aziridination transfer hydrogenation Organisk kemi Organic chemistry Organisk kemi
394	Developments in the Field of Aza-Diels-Alder Reactions, Catalytic Michael Additions and Automated Synthesis Modin, Stefan January 2004 (has links) <p>The development of new aza-bicyclic structures with potential applications as ligands synthesised <i>via</i> an aza-Diels-Alder cycloaddition has been studied. The studies are concerning the i) development of large scale aza-Diels-Alder reaction, ii) development of a fast and simple route to bicyclic diamine ligands, iii) development of new aza-Diels-Alder adducts from different dienes, iv) development and application of bicyclic N,P ligands for catalytic Michael additions and v) development of robotized asymmetric transfer hydrogenation reactions.</p><p>i) Development of large-scale aza-Diels-Alder reaction giving up to 110 g pure product, in ordinary laboratory equipment without the need of any flash chromatography.</p><p>ii) Development of a new synthetic route to bicyclic diamine ligands highly useful for asymmetric rearrangement of olefin oxides to allylic alcohols and thereby shortening the ligand synthesis dramatically and moreover providing with a faster access to those ligands.</p><p>iii) Expanding the scope of the aza-Diels-Alder reaction by the use of spirodienes and anthracene as dienes.</p><p>iv) Development and application of a new bidentate ligands for catalytic Michael addition to cyclic enones using 5 mol % ligand giving the product in 71 % ee.</p><p>v) Utilisation of Chemspeed ASW 2000 in catalytic transfer hydrogenation and solving of problems regarding use of highly air sensitive reactions in an automated environment.</p> Organic chemistry Asymmetric synthesis aza-Diels-Alder Michael addition Transfer hydrogenation automated synthesis Catalysis Organisk kemi Organic chemistry Organisk kemi
395	Design, Synthesis, Mechanistic Rationalization and Application of Asymmetric Transition-Metal Catalysts Hedberg, Christian January 2005 (has links) <p>This thesis describes mechanistic studies, rational ligand design, and synthesis of asymmetric transition metal catalysts. The topics addressed concerned [Papers I-VII]:</p><p>[I] The asymmetric addition of diethyl zinc to <i>N</i>-(diphenylphosphinoyl)benzalimine catalyzed by bicyclic 2-azanorbornyl-3-methanols was studied. An efficient route to both diastereomers of new bicyclic 2-azanorbornyl-3-methanols with an additional chiral center was developed, in the best case 97% ee was obtained with these ligands. The experimental results were rationalized by a computational DFT-study.</p><p>[II] An aza-Diels-Alder reaction of cyclopentadiene with chiral heterocyclic imines derived from (<i>S</i>)-1-phenylethylamine and different heteroaromatic aldehydes was developed. The cycloaddition proved to be highly diastereoselective and offers a very rapid access to possible biologically active compounds and interesting precursors for chiral (<i>P,N</i>)-ligands. </p><p>[III] A convenient and high-yielding method for the preparation of (<i>R</i>)-tolterodine, utilizing a catalytic asymmetric Me-CBS reduction was developed. Highly enantio-enriched (<i>R</i>)-6-methyl-4-phenyl-3,4-dihydrochromen-2-one (94% ee) was recrystallized to yield practically enantiopure material (ee >99%) and converted to (<i>R</i>)-tolterodine in a four-step procedure. </p><p>[IV] The reaction mechanism of the iridium-phosphanooxazoline-catalyzed hydrogenation of unfunctionalized olefins has been studied by means of DFT-calculations (B3LYP) and kinetic experiments. The calculations suggest that the reaction involves an unexpected IrIII-IrV catalytic cycle facilitated by coordination of a second equivalent of dihydrogen. On the basis of the proposed catalytic cycle, calculations were performed on a full system with 88 atoms. These calculations were also used to explain the enantioselectivity displayed by the catalyst.</p><p>[V and VI] A new class of chiral (<i>P,N</i>)-ligands for the Ir-catalyzed asymmetric hydrogenation of aryl alkenes was developed. These new ligands proved to be highly efficient and tolerate a broad range of substrates. The enantiomeric excesses are, so far, the best reported and can be rationalized using the proposed selectivity model.</p><p>[VII] The complex formed between the quincorine-amine, containing both a primary and a quinuclidine amino function, and [Cp*RuCl]<sub>4</sub> catalyzes the hydrogenation of aromatic and aliphatic ketones in up to 90% ee approx. 24-times faster than previously reported Ru-diamine complexes. The reason for the lower but opposite stereoselectivity seen with the quincoridine-amine, as compared to the quincorine-amine, was rationalized by a kinetic and computational study of the mechanism. The theoretical calculations also revealed a significantly lower activation barrier for the alcohol mediated split of dihydrogen, as compared to the non-alchol mediated process. A finding of importance also for the diphosphine/diamine mediated enantioselective hydrogenation of ketones.</p> Organic chemistry asymmetric catalysis homogeneous hydrogenation iridium ruthenium ligand design mechanistic studies kinetics tolterodine Organisk kemi Organic chemistry Organisk kemi
396	Materials for Hydrogen storage and synthesis of new materials by hydrogenation / Material för vätelagring och syntes av nya material genom hydrering Luzan, Serhiy January 2012 (has links) The search for new materials for hydrogen storage is important for the development of future hydrogen energy applications. In this Thesis, it is shown that new materials with interesting properties can be synthesized by the reaction of hydrogen with various nanocarbon precursors. The thesis consists of two parts. The first part is devoted to studies of hydrogen storage in some metal-organic frameworks (MOFs) and nanostructured carbon materials, while the second part describes synthesis of new materials by the reaction of hydrogen gas with various carbon materials (i.e. fullerene C60, single-walled carbon nanotubes (SWCNTs), and fullerene C60 encapsulated inside SWCNTs (C60@SWCNTs)). Hydrogen adsorption was measured for a set of Zn- and Co-based MOFs at near ambient temperatures. MOFs synthesized using different metal clusters and organic connecting ligands allowed to study effects of different surface area, pore volume, and pore shapes on hydrogen storage parameters. Hydrogen adsorption values in the studied MOFs correlated well with surface area and pore volume but did not exceed 0,75wt.%. Therefore, new methods to improve the hydrogen storage capacity in MOFs were investigated. The addition of metal catalysts was previously reported to improve significantly hydrogen storage in MOFs. In this thesis the effect of Pt catalyst addition on hydrogen adsorption in MOF-5 was not confirmed. Contrary to previous reports, hydrogen adsorption in MOF-5 mixed/modified with Pt catalysts had fast kinetics, correlated well with surface area, and was on the same level as for unmodified MOF-5. New nanostructured carbon materials were synthesized by the reaction between fullerene C60 and coronene/anthracene. Despite negligible surface area these materials adsorbed up to 0,45wt.% of hydrogen at ambient temperatures. The reaction of fullerene C60 with hydrogen gas was studied at elevated temperatures and hydrogen pressures. In situ gravimetric monitoring of the reaction was performed in a broad temperature interval with/without addition of metal catalysts (i.e. Pt and Ni). The reaction resulted in synthesis of hydrogenated fullerenes C60Hx (with x≤56) followed by fullerene cage fragmentation and collapse upon prolonged duration of hydrogen treatment. Possible mechanisms of C60 hydrogenation and fragmentation were discussed. It is demonstrated that reaction of SWCNTs with hydrogen gas at elevated temperatures and hydrogen pressures can be used for nanotube opening, purification from amorphous carbon, side-wall hydrogenation, and partial unzipping of SWCNTs. Some graphene nanoribbons (GNRs) were synthesized as the result of SWCNTs unzipping. A surprising ability of hydrogen to penetrate inside SWNTs and to react with encapsulated fullerene C60 was demonstrated. / Sökandet efter nya material för vätelagring är viktigt för utveckling av framtida väteenergitillämpningar. I denna avhandling visas att nya material med intressanta egenskaper kan syntetiseras genom reaktion av väte med olika nanokolprekursorer. Avhandlingen består av två delar. Den första delen ägnas åt studier av vätelagring i vissa metall-organiska fackverk (så kallade MOFs) och nanostrukturerade kolmaterial medan den andra delen beskriver syntes av nya material genom reaktion av vätgas med olika kolmaterial (dvs. fulleren C60, enkelväggiga kolnanorör (SWCNTs) och fulleren C60 kapslat i SWCNTs (C60 @ SWCNTs)). Väteadsorptionen mättes för ett antal Zn- och Co-baserade MOFs vid rumstemperatur. MOFs syntetiserades med hjälp av olika metallkluster och organiska ligander för att studera effekterna av olika yta, porvolym och porformer på vätelagringsparametrarna. Väteadsorptionsvärden i de studerade MOFs korrelerade väl med yta och porvolym, men översteg inte 0,75wt.%. Därför undersöktes nya metoder för att förbättra kapaciteten för vätelagring i MOFs. Tillsättning av metallkatalysatorer har tidigare rapporterats avsevärt förbättra vätelagring i MOFs. I denna avhandling kunde effekten av en tillsats av Pt-katalysator på väteadsorption i MOF-5 inte bekräftas. I motsats till tidigare rapporter hade väteadsorption i MOF-5 blandad/modifierad med Pt-katalysatorer snabb kinetik och korrelerade väl med arean, men var på samma nivå som för omodifierad MOF-5. Nya nanostrukturerade kolmaterial syntetiserades genom reaktion mellan fulleren C60 och coronene/antracene. Trots försumbar yta adsorberade dessa material upp till 0,45wt.% väte vid rumstemperatur. Reaktionen av fulleren C60 med vätgas studerades vid förhöjda temperaturer och vätetryck. In situ gravimetrisk övervakning av reaktionen utfördes i ett brett temperaturintervall med/utan tillsats av metallkatalysatorer (dvs. Pt och Ni). Reaktionen resulterade i syntes av hydrogenerade fullerener C60Hx (med x≤56) följt av fragmentering och kollaps av fullerenstrukturen vid förlängd varaktighet av vätebehandlingen. Möjliga mekanismer för hydrering och fragmentering av C60 diskuteras. Det har visats att reaktionen mellan SWCNTs och vätgas vid förhöjda temperaturer och vätetryck kan användas för öppning av nanorör, borttagning av amorft kol, funktionalisering av sidoväggar och partiell "blixtlåsöppning" av SWCNTs. Reaktionen kan också syntetisera grafen-nanoband (GNRs) som en följd av att SWCNTs öppnas på längden. En överraskande stor förmåga för väte att tränga in i SWNT och där reagera med inkapslade fullerenmolekyler C60 demonstrerades. Fullerene C60 MOFs CNTs SWCNTs PAHs peapods hydrogen hydrogen storage hydrogenation adsorption surface area pore volume spillover nanoribbons fragmentation
397	Concerted or Stepwise? : β-Elimination, Nucleophilic Substitution, Copper Catalysed Aziridination and Ruthenium Catalysed Transfer Hydrogenation Studied by Kinetic Isotope Effects and Linear Free-Energy Relationships Ryberg, Per January 2002 (has links) This thesis describes the use of kinetic isotope effects, linear free energy relationships and stereochamical studies to distinguish between different mechanistic alternatives and to obtain information about transition state structure. In the first part fluorine and deuterium kinetic isotope effects were determined for the base promoted HF elimination from 4-fluoro-4-(4’-nitrophenyl)butane-2-on. During this work a new method for the determination of fluorine kinetic isotope effects was developed. The results from the study demonstrates that the reaction proceeds via an E1cBip mechanism. In the second part the transition state structure for the SN2 reaction between ethyl chloride and cyanide ion in DMSO was studied. Kinetic isotope effects for six different positions in the reacting system, both in cyanide and ethyl chloride, were determined. The experimental isotope effects were then compared with the theoretically predicted isotope effects. The third part describes the use of Hammett type free-energy relationships and stereochemical evidence to study the mechanism of the copper catalysed alkene aziridination. The results from the study support a model that involves the simultaneous presence of two different copper nitrene intermediates. One which reacts non-stereospecifically via a radical intermediate and one which reacts stereospecifically via a concerted mechanism. In the fourth part a mechanistic study of the Ru(aminoalcohol) catalysed transfer hydrogenation of acetophenone in isopropanol is described. Kinetic isotope effects were determined for both proton and hydride transfer. The observation of significant primary deuterium kinetic isotope effects for both proton and hydride transfer support a mechanism where the proton and hydride are transferred simultaneously in a concerted mechanism. Organic chemistry Kinetic isotope effect linear free energy relationship elimination substitution aziridination transfer hydrogenation Organisk kemi Organic chemistry Organisk kemi
398	Developments in the Field of Aza-Diels-Alder Reactions, Catalytic Michael Additions and Automated Synthesis Modin, Stefan January 2004 (has links) The development of new aza-bicyclic structures with potential applications as ligands synthesised via an aza-Diels-Alder cycloaddition has been studied. The studies are concerning the i) development of large scale aza-Diels-Alder reaction, ii) development of a fast and simple route to bicyclic diamine ligands, iii) development of new aza-Diels-Alder adducts from different dienes, iv) development and application of bicyclic N,P ligands for catalytic Michael additions and v) development of robotized asymmetric transfer hydrogenation reactions. i) Development of large-scale aza-Diels-Alder reaction giving up to 110 g pure product, in ordinary laboratory equipment without the need of any flash chromatography. ii) Development of a new synthetic route to bicyclic diamine ligands highly useful for asymmetric rearrangement of olefin oxides to allylic alcohols and thereby shortening the ligand synthesis dramatically and moreover providing with a faster access to those ligands. iii) Expanding the scope of the aza-Diels-Alder reaction by the use of spirodienes and anthracene as dienes. iv) Development and application of a new bidentate ligands for catalytic Michael addition to cyclic enones using 5 mol % ligand giving the product in 71 % ee. v) Utilisation of Chemspeed ASW 2000 in catalytic transfer hydrogenation and solving of problems regarding use of highly air sensitive reactions in an automated environment. Organic chemistry Asymmetric synthesis aza-Diels-Alder Michael addition Transfer hydrogenation automated synthesis Catalysis Organisk kemi Organic chemistry Organisk kemi
399	Design, Synthesis, Mechanistic Rationalization and Application of Asymmetric Transition-Metal Catalysts Hedberg, Christian January 2005 (has links) This thesis describes mechanistic studies, rational ligand design, and synthesis of asymmetric transition metal catalysts. The topics addressed concerned [Papers I-VII]: [I] The asymmetric addition of diethyl zinc to N-(diphenylphosphinoyl)benzalimine catalyzed by bicyclic 2-azanorbornyl-3-methanols was studied. An efficient route to both diastereomers of new bicyclic 2-azanorbornyl-3-methanols with an additional chiral center was developed, in the best case 97% ee was obtained with these ligands. The experimental results were rationalized by a computational DFT-study. [II] An aza-Diels-Alder reaction of cyclopentadiene with chiral heterocyclic imines derived from (S)-1-phenylethylamine and different heteroaromatic aldehydes was developed. The cycloaddition proved to be highly diastereoselective and offers a very rapid access to possible biologically active compounds and interesting precursors for chiral (P,N)-ligands. [III] A convenient and high-yielding method for the preparation of (R)-tolterodine, utilizing a catalytic asymmetric Me-CBS reduction was developed. Highly enantio-enriched (R)-6-methyl-4-phenyl-3,4-dihydrochromen-2-one (94% ee) was recrystallized to yield practically enantiopure material (ee >99%) and converted to (R)-tolterodine in a four-step procedure. [IV] The reaction mechanism of the iridium-phosphanooxazoline-catalyzed hydrogenation of unfunctionalized olefins has been studied by means of DFT-calculations (B3LYP) and kinetic experiments. The calculations suggest that the reaction involves an unexpected IrIII-IrV catalytic cycle facilitated by coordination of a second equivalent of dihydrogen. On the basis of the proposed catalytic cycle, calculations were performed on a full system with 88 atoms. These calculations were also used to explain the enantioselectivity displayed by the catalyst. [V and VI] A new class of chiral (P,N)-ligands for the Ir-catalyzed asymmetric hydrogenation of aryl alkenes was developed. These new ligands proved to be highly efficient and tolerate a broad range of substrates. The enantiomeric excesses are, so far, the best reported and can be rationalized using the proposed selectivity model. [VII] The complex formed between the quincorine-amine, containing both a primary and a quinuclidine amino function, and [Cp*RuCl]4 catalyzes the hydrogenation of aromatic and aliphatic ketones in up to 90% ee approx. 24-times faster than previously reported Ru-diamine complexes. The reason for the lower but opposite stereoselectivity seen with the quincoridine-amine, as compared to the quincorine-amine, was rationalized by a kinetic and computational study of the mechanism. The theoretical calculations also revealed a significantly lower activation barrier for the alcohol mediated split of dihydrogen, as compared to the non-alchol mediated process. A finding of importance also for the diphosphine/diamine mediated enantioselective hydrogenation of ketones. Organic chemistry asymmetric catalysis homogeneous hydrogenation iridium ruthenium ligand design mechanistic studies kinetics tolterodine Organisk kemi Organic chemistry Organisk kemi
400	Synthesis and Evaluation of N,P-Chelating Ligands in Asymmetric Transition-Metal-Catalyzed Reactions : Ir-Catalyzed Asymmetric Hydrogenation and Pd-Catalyzed Asymmetric Intermolecular Heck Reaction Tolstoy, Päivi January 2009 (has links) This thesis describes synthesis of new chiral N,P ligands and their evaluation in two types of asymmetric transition-metal catalyzed reactions. The first part of the thesis describes studies in iridium-catalyzed asymmetric hydrogenation. A new class of chiral N,P ligands, imidazole-phosphines, was synthesized and evaluated in the Ir-catalyzed asymmetric hydrogenation of olefins (Paper I). The new ligands proved to be highly efficient and enantioselective in the reaction. Because the substrate scope of Ir-catalyzed asymmetric hydrogenation is still limited to certain types of test substrates, new substrate classes with importance in medicinal and materials chemistry were investigated. Vinyl fluorides were efficiently hydrogenated to fluorine-containing chiral centers by the iridium catalysts with imidazole-phosphine ligands (Paper I). To obtain CF3-bearing chiral centers, we hydrogenated CF3-substituted olefins (Paper II). Ir-catalyzed asymmetric hydrogenation was highly enantioselective for the functionalized CF3-substituted olefins and the resulting chiral products can be valuable in design of materials such as LCD screens. Ir-catalyzed asymmetric hydrogenation was also evaluated as a route to diarylmethine chiral centers (Paper III). A wide range of new chiral compounds possessing a diarylmethine chiral center was obtained. The second part of the thesis deals with asymmetric intermolecular Heck reaction utilizing N,P ligands. The N,P ligand class of thiazole-phosphines was evaluated in the Heck reaction (Paper IV) and gave high enantioselectivity. Further, the intermolecular Heck reaction was examined using computational and experimental studies (Paper V). This study led to a better understanding of the enantioselectivity in the reaction. Asymmetric hydrogenation Heck reaction N P ligand Iridium Palladium Asymmetric catalysis Alkenes Fluorine Diarylmethine stereocenters Chemistry Kemi

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