A study of the role of carbonate supports for rhodium catalyst in hydrogenation reactions

Yeung, Patrick Pui-Hang

08 1900

No description available.

Hydrogenation

Platinum group catalysts

New ruthenium catalysts for asymmetric hydrogenation /

Díaz Valenzuela, María Belén.

January 2007

Thesis (Ph.D.) - University of St Andrews, November 2007. / Restricted until 15th November 2008.

Developments in late metal-mediated C-N bond forming reactions /

Pawlikowski, Andrew V.

January 2006

Thesis (Ph. D.)--University of Washington, 2006. / Vita. Includes bibliographical references (leaves 186-194).

Phase relations in the system Cu-Fe-Ni-S and their application to the slow cooling of PGE matte

Viljoen, Willemien

13 October 2005

Please read the abstract in the section 00front of this document / Thesis (PhD)--University of Pretoria, 2006. / Geology / Unrestricted

Platium group industry

Platinum group catalysts

Ore-dressing

UCTD

Electrolysis of ammonia effluents a remediation process with co-generation of hydrogen /

Bonnin, Egilda Purusha.

January 2006

Thesis (M.S.)--Ohio University, August, 2006. / Title from PDF t.p. Includes bibliographical references.

Enantioselective hydrogenation using ruthenium complexes of tridentate ligands

Phillips, Scott D.

January 2011

This thesis describes the development of the [RuCl₂(P N N)L] catalytic system for asymmetric hydrogenation. It has been demonstrated that the current system is efficient in preparing a range of bulky chiral alcohols in good enantioselectivity, many of which are likely to be inaccessible using the more classic [RuCl₂(P P)N N)] system developed by Noyori and coworkers. It has been shown that the current system is tolerant of a range of substrate electronic effects as well as the presence of heteroaromatic functionality, thus showing its applicability in synthesis. This has been extended to prepare a number of bulky derivatives of synthetically important molecules. The demonstration of this is significant as in drug design, for example, studies that aim to extend lipophilicity or steric bulk make the ability to prepare alcohols across the full range of steric properties important. We have shown that chiral alcohols with adjacent gem-dimethyl groups can be prepared in high enantioselectivity and their conversion into other valuable molecules, such as chiral lactones has been demonstrated. Detailed mechanistic studies have been undertaken for the present system in order to aid rational design of new, more active and selective catalysts. A number of achiral variants of the original system have been prepared and the key features of ligand structure for efficient catalysis have been identified. This was accomplished by rigorous kinetic analysis of each complex, using specialist gas-uptake monitoring equipment. The key features of catalyst structure and optimal reaction conditions for efficient asymmetric hydrogenation have been identified. Our greater understanding of the present system allowed us to rationally design new catalysts of for enantioselective hydrogenation. Our aim was to be able to tune the catalyst structure to carry out hydrogenation of a greater variety of ketone substrate with high activity and selectivity. We have successfully prepared second generation catalysts that show enhanced enantioselectivity for a variety of substrates, many of which were problematic with the Noyori system.

541.39

Carbon monoxide hydrogenation using ruthenium catalysts

Blank, Jan Hendrik

January 2012

No description available.

Towards new catalytic systems for the formation of methyl methacrylate from methyl propanoate

Coetzee, Jacorien

January 2011

The two stage Lucite Alpha Process for the industrial manufacturing of methyl methacrylate (MMA) represents one of the most efficient technologies currently available for the large scale production of this important chemical commodity. The second stage of this process, which involves the condensation of methyl propanoate (MeP) with formaldehyde over a heterogeneous fixed bed catalyst, however, still shows great scope for improvement. Herein the development of a novel homogeneous catalytic system that would promote the condensation of either propanoic acid or MeP with formaldehyde is explored. Since C–C bond forming reactions which proceed via C–H activation pathways typically display high atom efficiency, our efforts were particularly focussed on employing a functionalisation strategy that is mediated by C–H activation. In the case of propanoic acid, the possibility of achieving regioselective α-methylenation by linking the substrate to phosphorus was evaluated. Thus, a series of acyloxyphosphines and acylphosphites derived from either propionic acid or phenylacetic acid was prepared and, where stability allowed, fully characterised. Some of the resultant simple mixed anhydrides posed problems relating to their stability, and the stabilisation of such ligand systems by using electronic and / or steric effects was therefore explored. In addition, the coordination chemistry and in solution behaviour of Rh(I) and Ru(II) complexes containing these ligands was examined. Similar to the free ligands, complexes derived from these mixed anhydrides rearranged in solution via a number of decomposition pathways, with the specific pathway dependent on the nature of the auxiliary ligands. For most of these complexes, however, ligand decarbonylation was the route of preference for decomposition. Despite the instability of these complexes, a selection of Rh(I) mixed anhydride complexes were assessed for their potential as C-H activation catalysts in reactions aimed at the α-methylenation of saturated carboxylic acids. Furthermore, the stabilisation of Rh(I) mixed anhydride complexes with chelating auxilary ligands, such as bisphosphines or N-substituted diphosphinoamines, was explored. In particular, a series of new Rh(I) mixed anhydride complexes containing dppe, dppb and dppbz as secondary ligands were prepared and the effects of these secondary ligands on the in solution stability of these complexes assessed. As MeP represents the final product in the first stage of the Alpha process and not propanoic acid, the utilisation of PNP iridium pincer complexes in the regioselective sp³ C–H activation of MeP and related esters was also examined. The factors that govern the regioselectivity of such reactions were of great interest to us and, in particular, the effects of water on the reactivity and regioselectivity of these reactions were explored. For MeP, preferential C–H activation of the methoxy group was found to proceed under anhydrous conditions and the catalytic functionalisation of this site with ethene using this activation approach was considered. Formaldehyde, employed in the second stage of the Alpha process, is a difficult substance to manufacture and handle, especially on a large scale. A preliminary study on the in situ production of anhydrous formaldehyde via the catalytic dehydrogenation of methanol was therefore performed. During this study, catalytic systems based on carbonate salts and / or transition metal complexes were considered. In the hope of reducing the number of steps required in the production of MMA, a new one-pot cascade reaction for the indirect α-methylenation of MeP with methanol was developed. Although the production of MMA using this system only proceeded with low efficiency, the obtained results serve as an important proof of concept for future developments in this area. Finally, the capacity of a series of simple bases to catalyse the condensation of MeP with formaldehyde was assessed as part of a fundamental study directed towards determining the factors that govern the efficiency of this reaction. In addition, the extent to which each base effects the deprotonation in the α-position of MeP was determined with the aid of deuterium labelling experiments. Similarly, using sodium propanoate as model base a rough estimate of the kinetics of deprotonation could be made based on the degree of deuterium incorporation over time. These studies suggested that the low efficiency of this condensation reaction is not caused by ineffective deprotonation but rather by the weak nucleophilicity of the generated carbanion. For this reason, attempts to increase the electrophilicity of formaldehyde through Mannich-type condensations reactions involving secondary amine and carboxylic acid additives were made.

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