Synthesis, characterization and kinetic investigations of heterophase materials prepared using group transfer polymerization

Hellstern, Ann Marie

January 1989

The impact of multiphase polymeric materials has been enhanced by the preparation of well defined block and graft copolymers. Hence, there has been a growing emphasis on new synthetic methods for the preparation of blocks and grafts. Group Transfer Polymerization (GTP) is a relatively new synthetic method which provides a means to obtain poly(alkyl acrylate)s and poly(alkyl methacrylate)s via a "living" mechanism over a broad temperature range. The degree of control over molecular weight and molecular weight distribution rivals that afforded through living anionic techniques for the preparation of poly(alkyl methacrylate)s. The objectives of this research were many fold. The first was to establish GTP as a routine synthetic tool for the preparation of poly(alkyl methacrylate)s in our laboratories. This involved utilizing a variety of initiators, catalysts and alkyl methacrylate monomers. Furthermore, kinetic studies of the GTP of MMA with a controlled temperature, "living" polymerization reactor and tetrabutylammonium benzoate as the selected catalyst were initiated. These investigations involved the determination of the reaction order with respect to initiator and catalyst concentrations. Also, the global energy of activation, under controlled reaction conditions, was elucidated. To extend the synthetic utility of GTP, novel block and graft copolymers were synthesized. Transformation reactions and the macromonomer technique to interrelate different synthetic routes further extends the range of block and graft copolymers which can be prepared. Poly(dimethylsiloxane) (PDMS) macromers were prepared via the anionic ring opening polymerization of hexamethylcyclotrisiloxane, which is subsequently terminated with a chlorosilane derivative of allyl methacrylate. The macromonomer technique has been employed to synthesize poly(methyl— methacrylate)—g-poly(dimethylsiloxane) copolymers of controlled molecular weight and apparent narrow molecular weight distribution by GPC. Transformation of the methacrylate functional group on the PDMS provided a suitable macroinitiator for the GTP of methyl methacrylate, which leads to siloxane-b-methacrylate copolymers via a novel route. / Ph. D.

LD5655.V856 1989.H444

Polymerization

Catalysis

Base catalysis by alkali modified zeolites

Hathaway, Paul Edward

January 1989

The development, characterization, and catalytic application of a novel zeolite with solid base properties has been completed. From isopropanol decomposition to acetone and propylene, the acid/base properties of various alkali exchanged, faujasite-type zeolites are explored. It is found that upon impregnation of CsNaY with cesium hydroxide or cesium acetate, acetone production (normally attributed to base sites) is promoted by an order of magnitude above the untreated (not impregnated) CsNaY zeolite. Furthermore, selectivity to acetone is above 97% and on a surface area basis, acetone activity is found to be comparable to MgO. Impregnation of CsNaX shows little promotion in acetone activity resulting in acetone activity comparable to the untreated CsNaY zeolite and acetone selectivity at 62%. From numerous characterization studies of the impregnated CsNaY zeolite (many in situ) it appears that a highly dispersed intracrystalline cesium oxide is formed from the decomposition of the occluded salt and is believed to be the active site for acetone formation. Evidence is provided also to indicate the presence of an isopropoxide intermediate which is responsible for the acetone and the minor amounts of propylene formed by the acetate impregnated CsNaY zeolite. The cesium acetate impregnated CsNaY catalyst was tested for activity by the base catalyzed alkylation of toluene, acetone, ethane, and methane with methanol. For toluene alkylation, it is determined that little improvement is gained over previous faujasite-type catalysts. This appears to be a result of the rapid decomposition of formaldehyde, i.e., the alkylating agent derived from the dehydrogenation of methanol. MgO is demonstrated to possess base properties similar to the acetate impregnated CsNaY zeolite, yet MgO is found to be inactive in toluene alkylation. Neither ethane or methane is alkylated at 425°C or 465°C by the acetate impregnated zeolites. Acetone is alkylated slightly to methylvinylketone and methylethylketone at 425°C but the majority of the reacted acetone appears to form aldol condensation products. / Ph. D.

LD5655.V856 1989.H373

Zeolites

Catalysis

Ammonia decomposition by plasma catalysis

Shawon, Minhazur Rahman

13 August 2024

Ammonia decomposition plays a crucial role in various industrial and environmental processes, including the production of hydrogen, clean energy storage. Plasma catalysis presents a promising option that utilizes the unique properties of plasma to drive chemical reactions at a lower temperature than traditional methods. This study examines the effectiveness of plasma catalysis for ammonia decomposition on ruthenium (Ru) supported on alumina (Al₂O₃) as the catalyst. The research indicates that the catalytic performance of Ru is significantly impacted by its loading on the alumina support. The study identifies optimal Ru loading conditions, which lead to substantial improvements in ammonia decomposition. The incorporation of alkali metal promoters, such as sodium (Na), potassium (K), lithium (Li), and cesium (Cs), enhances the catalytic activity, especially at lower Ru loadings (0.01%). This study highlights the potential of Ru-based catalysts with alkali metal promoters in plasma catalytic systems for efficient ammonia decomposition.

Application-Focused Investigation of Monovalent Metal Complexes for Nanoparticle Synthesis

Kamras, Brian Leon

08 1900

Over the last 20 years, there has occurred an increase in the number, scope, and impact of nanomaterials projects. By leveraging the Surface Plasmon Resonance of metallic nanoparticles for labelling, sensing, and treatment, researchers have demonstrated the versatile utility of these nanomaterials in medicine. The literature provides evidence of use of simple, well-known chemistry for nanomaterials synthesis when the focus is new applications of nanomaterials. A case in point, is the synthesis of metallic nanoparticles, whereby HAuCl4, CuCl2, Cu(acac)2, and AgNO3 are typically employed as nanoparticle precursors. Unfortunately, the use of these precursors limits the number of applications available to these materials - particularly for AuNPs in medicine, where the byproducts of nanoparticle synthesis (most often surface-adsorbed reductants, toxic stabilizers, and growth directors) cause nanoparticles to fail clinical trials. Despite the several thousand publications detailing the advancements in nanoparticle therapeutics, as of 2017, there were only 50 FDA-approved nanoparticle formulations. Less than 10 were based on metallic nanoparticles. This is a problem because many of these nanoparticle therapeutics demonstrate potent cell killing ability and labeling of cells. A solution to this problem may be the use of weakly coordinated, monovalent metal complexes, which require only one electron to reduce them to their metallic state. Further, by designing nanoparticle syntheses around these monovalent complexes, we can employ weaker, environmentally friendly stabilizers. This strategy also forgoes the use of exogenous reducing agents, because the monovalent complexes can be reduced and stabilized by one reagent. Herein we investigate the use of Au(Me2S)Cl, [Cu(MeCN)4]BF4, and AgBF4 with green stabilizers to synthesize a variety of nanomaterials. We find that a range of sizes of spherical particles, as well as a range of sizes of gold triangular prisms can be synthesized by using techniques that follow this strategy.

Nanoparticles

Non-toxic

catalysis

green

metal-organic framework

Cation-controlled diastereo- and enantioselective synthesis of indolines : an autocatalytic process

Sharma, Krishna

January 2014

Asymmetric phase-transfer catalysis is a powerful technique that enables a wide range of transformations under mild conditions, often using inexpensive and environmentally benign reagents. By extending the applications of phase-transfer catalysis we have developed a highly diastereo- and enantioselective synthesis of functionalized indolines bearing two contiguous stereocentres, one of which is quaternary and all carbon, in a single synthetic step. The reaction proceeds with complete diastereoselectivity and with high levels of enantioselectivity (up to 99% ee). Despite the development of phase-transfer catalysis as a primary synthetic tool in organic synthesis, the mechanistic understanding of these reactions still remains a challenge, due mainly to the difficulty of studying the complex multi-phase systems. Therefore, a further aim of this project was to understand the reaction mechanism of our phase-transfer catalysed transformation. Investigations into the mechanism of our phase-transfer catalysed reaction have been carried out by studying the reaction kinetics. These have shown that the reaction follows a sigmoidal curve with an induction period present. A detailed kinetic investigation was carried out which demonstrated that an autocatalytic mechanism is operational.

547

A non-syn-gas catalytic route to methanol production

Wu, Cheng-Tar

January 2013

At present, more than 80% of the world’s energy consumption and production of chemicals is originated from the use of fossil resources. There is a tremendous growing interest in utilising biomass molecules for energy provision due to their carbon neutrality. Lower alcohols such as methanol and ethanol if produced from biomass as transportation fuels as well as platform chemicals, can become strategically important for many energy/chemically starved countries. Currently, they are synthesised by indirect and inefficient processes. We show for the first time in this thesis study that ethylene glycol, the simplest representative of biomass-derived polyols, can be directly converted to these two lower alcohols by selective hydrogenolysis over modified Raney Ni and Cu catalysts in hydrogen atmosphere. This work provides essential information that may lead to the development of new catalysts for carbohydrate activation to methanol, a novel but important reaction concerning the important biomass conversion to transportable form of energy. Modification of electronic structure and the adsorption properties of Raney catalysts have therefore been achieved by blending with second metal(s). It is found that the activity and selectivity of this reaction can be significantly affected by this approach. In contrast, there is no subtle effect on methanol selectivity despite a great variation in the d-band centre positions of metal catalysts which show a distinctive effect on other products. Our result suggests that methanol is produced on specific surface sites independent from the other sites at an intrinsic rate and will not be converted to other products by the d-band alteration. On the other hand, it is reported in this thesis that a dramatic improvement in the combined selectivity to methanol/ethanol reaching 80% can be obtained over a Pd/Fe₃O₄ catalyst under relatively milder conditions (20 bar and 195 oC). This direct production of the non-enzymatic bio-alcohols is established over a carefully prepared co-precipitated Pd/Fe₃O₄ catalyst which gives a metallic phase of unexpectedly high dispersion ranging from small clusters to individual metal adatoms on defective iron oxide to give the required metal-support interaction for the novel synthesis. It is demonstrated that the small PdFe clusters on iron oxide surface provide the active species responsible for methanol production. In addition, a related Rh/Fe₃O₄ catalyst synthesised by co-precipitation is also shown to be selective for CO₂ and H₂ production from a direct methane-oxygen oxidation reaction. As a result, 2.7% conversion of methane with selectivity ratio of CO₂/H₂ = 4 in a mixed gas feed stream of CH₂/O₂ = 30 at 300 ^oC is obtained. The reaction is operated in a kinetically controlled regime at 300^oC, where the CO formation from reverse water gas shift reaction is greatly suppressed. It is evident that the Rh/Fe₃O₄ acts as an interesting bifunctional catalyst for this reaction. This catalyst firstly gives a high dispersion of Rh which is expected to deliver a higher surface energy with enhanced activity. The Rh metal surface provides catalytically active sites for dissociation of methane to adsorbed hydrogen and carbon atoms effectively, and active oxygen on metal surface readily catalyses the carbon atoms to CO. Following these elementary reactions, the surface oxygen from Fe₃O₄ subsequently converts it to CO₂ selectively at the metal-support interface. As a result, the novel study of catalytic biomass conversion and the discoveries of new catalysts are reported in this thesis.

662.6

Novel chiral wide bite angle ligands for asymmetric catalysis

Czauderna, Christine F.

January 2013

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

An investigation of new heterogeneous hydrotalcite-like catalysts for the cis-dihydroxylation of olefins.

Govender, Mayashree.

January 2004

The use of supported catalysts to essentially combine the positive traits offered by both homogeneous and heterogeneous catalysis has become a competitive field of research. In particular, hydrotalcite-like catalysts (HTIc) has proven to be valuable for this purpose. Various osmium - containing catalysts were synthesized according to the co-precipitation method viz. Os-Cu-HTIc, Os-Ni-HTlc and the Os-Co-HTlc. Techniques such as SEM, IR, EDS, XRD, ICP, BET and XPS were exploited during catalyst characterisation and these essentially confirm that the hydrotalcite (HT) structure has been obtained. Various olefin substrates, ranging from simple straight-chained alkenes to cyclic, allylic and halogenated olefins, were tested. The results are promising and suggest that the diols are produced both with high selectivity and in good yield. Further experiments suggest: 1) Ofthe various co-oxidants tested, N-methylmorpholine-N-oxide is most suitable 2) The reaction proceeds faster at 60 °C than at room temperature 3) The addition of water to the reaction mixture increases the rate of the reaction for most substrates and 4) The catalyst is thermally stable and produces better results when calcined at 200 0 C prior to use This thesis reports that a new heterogeneous catalytic system for the efficient and selective cisdihydroxylation of olefins has been developed - one which suggests no leaching of metal into the reaction solution and no over-oxidation products. / Thesis (M.Sc.)-University of KwaZulu Natal, 2004.

Catalysis.

Organic compounds--Synthesis.

Olefins.

Leaching.

Theses--Chemistry.

Chemical equilibrium.

Metal catalysts.

Heterogeneous catalysis.

Palladium-Catalyzed C(sp2)-C(sp3) Bond Formation

Rousseaux, Sophie

16 July 2012

Palladium-catalyzed reactions for carbon-carbon bond formation have had a significant impact on the field of organic chemistry in recent decades. Illustrative is the 2010 Nobel Prize, awarded for “palladium-catalyzed cross couplings in organic synthesis”, and the numerous applications of these transformations in industrial settings. This thesis describes recent developments in C(sp2)-C(sp3) bond formation, focusing on alkane arylation reactions and arylative dearomatization transformations. In the first part, our contributions to the development of intramolecular C(sp3)-H arylation reactions from aryl chlorides are described (Chapter 2). The use of catalytic quantities of pivalic acid was found to be crucial to observe the desired reactivity. The reactions are highly chemoselective for arylation at primary aliphatic C-H bonds. Theoretical calculations revealed that C-H bond cleavage is facilitated by the formation of an agostic interaction between the palladium centre and a geminal C-H bond. In the following section, the development of an alkane arylation reaction adjacent to amides and sulfonamides is presented (Chapter 3). The mechanism of C(sp3)-H bond cleavage in alkane arylation reactions is also addressed through an in-depth experimental and theoretical mechanistic study. The isolation and characterization of an intermediate in the catalytic cycle, the evaluation of the roles of both carbonate and pivalate bases in reaction mechanism as well as kinetic studies are reported. Our serendipitous discovery of an arylation reaction at cyclopropane methylene C-H bonds is discussed in Chapter 4. Reaction conditions for the conversion of cyclopropylanilines to quinolines/tetrahydroquinolines via one-pot palladium(0)-catalyzed C(sp3)-H arylation with subsequent oxidation/reduction are described. Initial studies are also presented, which suggest that this transformation is mechanistically unique from other Pd catalyzed cyclopropane ring-opening reactions. Preliminary investigations towards the development of an asymmetric alkane arylation reaction are highlighted in Chapter 5. Both chiral carboxylic acid additives and phosphine ligands have been examined in this context. While high yields and enantiomeric excesses were never observed, encouraging results have been obtained and are supported by recent reports from other research groups. Finally, in part two, the use of Pd(0)-catalysis for the intramolecular arylative dearomatization of phenols is presented (Chapter 7). These reactions generate spirocyclohexadienones bearing all-carbon quaternary centres in good to excellent yields. The nature of the base, although not well understood, appears to be crucial for this transformation. Preliminary results in the development of an enantioselective variant of this transformation demonstrate the influence of catalyst activation on levels of enantiomeric excess.

palladium catalysis

C-H functionalization

alkane arylation

dearomatization

asymmetric catalysis

mechanistic studies

Part A: Rhodium-catalyzed Synthesis of Heterocycles / Part B: Mechanistic Studies on Tethering Organocatalysis Applied to Cope-type Alkene Hydroamination

Guimond, Nicolas

29 August 2012

The last decade has been marked by a large increase of demand for green chemistry processes. Consequently, chemists have focused their efforts on the development of more direct routes toward different classes of targets. In that regard catalysis has played a crucial role at enabling key bond formations that were otherwise inaccessible or very energy and resources consuming. The central theme of this body of work concerns the formation of C–N bonds, either through transition metal catalysis or organocatalysis. These structural units being highly recurrent in biologically active molecules, the establishment of more efficient routes for their construction is indispensable. The first part of this thesis describes a new method for the synthesis of isoquinolines from the oxidative coupling/annulation of alkynes with N-tert-butyl benzaldimines via Rh(III) catalysis (Chapter 2). Preliminary mechanistic investigations of this system pointed to the involvement of Rh(III) in the C–H bond cleavage step as well as in the C–N bond reductive elimination that provides the desired heterocycle. Following this oxidative process, a Rh(III)-catalyzed redox-neutral approach to isoquinolones from the reaction of benzhydroxamic acids with alkynes is presented (Chapter 3). The discovery that an N–O bond contained in the substrate can act as an internal oxidant was found to be very enabling. Indeed, it allowed for milder reaction conditions, broader scope (terminal alkyne and alkene compatible) and low catalyst loadings (0.5 mol%). Mechanistic investigations on this system were also conducted to identify the nature of the C–N bond formation/N–O bond cleavage as well as the rate-determining step. The second part of this work presents mechanistic investigations performed on a recently developed intermolecular hydroamination reaction catalyzed through tethering organocatalysis (Chapter 4). This transformation operates via the reversible covalent attachment of two reactants, a hydroxylamine and an allylamine, to an aldehyde catalyst by the formation of a mixed aminal. This allows a difficult intermolecular Cope-type hydroamination to be performed intramolecularly. The main kinetic parameters associated with this reaction were determined and they allowed the generation of a more accurate catalytic cycle for this transformation. Attempts at developing new families of organocatalysts are also discussed.

Heterocycle Synthesis

Isoquinoline

Isoquinolone

Catalysis

Organocatalysis

Alkene Hydroamination

Rhodium(III) Catalysis