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Model Studies of Proposed Intermediates in Homogeneous Gold(I) Catalysis

dc.contributor.advisor Widenhoefer, Ross A
dc.contributor.author Brown, Timothy Justin
dc.date.accessioned 2012-09-04T13:15:23Z
dc.date.available 2014-08-25T04:30:04Z
dc.date.issued 2012
dc.identifier.uri https://hdl.handle.net/10161/5802
dc.description.abstract <p>The ability of gold(I) complexes to function as catalysts for myriad organic transformations has led to a dramatic increase in their utilization. Among the homogeneous reactions catalyzed by gold(I), carbon-carbon and carbon-heteroatom bond forming processes are of particular interest for the fields of organic synthesis and pharmaceutical development. Discussed herein are gold(I)-catalyzed methods for the intra- and intermolecular functionalization of alkenes, alkynes, and allenes with nitrogen- and oxygen-based nucleophiles leading to new C&#8210;X bonds (X = N, O).</p><p>Approximately 26 cationic gold &pi;-alkene complexes, containing either IPr [IPr = 1,3-bis(2,6-diisopropylphenyl)imidazol-2-ylidene] or P(t-Bu)2o-biphenyl ancillary ligands, were isolated or generated and six complexes were analyzed by X-ray crystallography. Spectroscopy, X-ray crystallography, and alkene binding studies are in accord with a gold&#8722;(&#960;-alkene) interaction dominated by &sigma;-donation from the alkene to gold. Kinetic analyses of degenerate isobutylene exchange in both the IPr and phosphine systems are consistent with associative pathways for isobutylene exchange involving cationic bis(alkene) intermediates.</p><p>Reaction of a 1:1 mixture of (L)AuCl [L = P(t-Bu)<sub>2</sub>o-biphenyl or IPr] and AgSbF<sub>6</sub> with internal alkynes led to isolation of the corresponding cationic, two-coordinate gold &pi;-alkyne complexes in &#8805;90% yield. Equilibrium binding studies show that the binding affinities of alkynes to gold(I) are strongly affected by the electron density of the alkyne and to a lesser extent on the steric bulk of the alkyne. Treatment of a suspension of (IPr)AuCl and AgSbF<sub>6</sub> with terminal arylacetylenes led to the formation of thermally unstable gold &pi;-alkyne complexes of the form [(IPr)Au(eta<super>2</super>-HC&#8801;CAr)] SbF<sub>6</sub> in &#8805;86 ± 5% yield, which were characterized by spectroscopy without isolation. Warming these complexes to 0 °C led to C(sp)-H bond cleavage and formation of dinuclear gold(I) &sigma;,&pi;-acetylide complexes of the form {[(IPr)Au]<sub>2</sub>(eta<super>1</super>,eta<super>2</super>-C&#8801;CAr)} SbF<sub>6</sub>, three of which were isolated in 99% yield and one of which was characterized by X-ray crystallography.</p><p>A family of 7 cationic gold(I) &pi;-allene complexes were isolated and fully characterized in solution, and in three cases by X-ray crystallography. Degenerate intermolecular allene exchange kinetic studies for three of the allene complexes are in accord with a two-term rate law of the form rate = k1[complex] + k2[complex][allene] with with Gibb's free energy barriers of 17.4 - 18.8 kcal mol<super>-1</super> (1) and 15.2 - 17.6 kcal mol<super>-1</super> (2). Variable temperature NMR analysis of these complexes established facile intramolecular &#61552;-face exchange through &#61544;1-allene intermediates or transition states with barriers of 8.9 - 10.9 kcal mol<super>-1</super> for phosphine and 9.5 - 12.2 kcal mol<super>-1</super> for IPr complexes.</p><p>Mechanistic investigation of gold(I)-catalyzed intramolecular allene hydroalkoxylation established a mechanism involving rapid and reversible C-O bond formation followed by turnover-limiting protodeauration from a mono(gold) vinyl complex. This on-cycle pathway competes with catalyst aggregation and formation of an off-cycle bis(gold) vinyl complex.</p>
dc.subject Chemistry
dc.subject Organic chemistry
dc.subject Inorganic chemistry
dc.subject bis(gold) complexes
dc.subject gold
dc.subject kinetics
dc.subject mechanism
dc.subject pi-complexes
dc.title Model Studies of Proposed Intermediates in Homogeneous Gold(I) Catalysis
dc.type Dissertation
dc.department Chemistry
duke.embargo.months 24


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