Formation of Bonds to Carbon at Transition Metal Centers

Formation of Bonds to Carbon at Transition Metal Centers

<p>The reactions of Cp<sub>2</sub>TiCH<sub>2</sub>Al(Me)<sub>2</sub>Cl 1, Cp<sub>2</sub>TiCH<sub>2</sub>C(R) = CR 2, and Cp<sub>2</sub>TiCH<sub>2</sub>CHRCH<sub>2</sub> 3 with organic carbonyl compo...

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Main Author: Brown-Wensley, Katherine Ann
Format: Others
Language:en
Published: 1981
Online Access:https://thesis.library.caltech.edu/10749/1/Brown-Wensley_KA_1981.pdf
Brown-Wensley, Katherine Ann (1981) Formation of Bonds to Carbon at Transition Metal Centers. Dissertation (Ph.D.), California Institute of Technology. doi:10.7907/sz44-eg97. https://resolver.caltech.edu/CaltechTHESIS:03022018-142501266 <https://resolver.caltech.edu/CaltechTHESIS:03022018-142501266>
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spelling ndltd-CALTECH-oai-thesis.library.caltech.edu-107492021-04-17T05:02:09Z https://thesis.library.caltech.edu/10749/ Formation of Bonds to Carbon at Transition Metal Centers Brown-Wensley, Katherine Ann <p>The reactions of Cp<sub>2</sub>TiCH<sub>2</sub>Al(Me)<sub>2</sub>Cl 1, Cp<sub>2</sub>TiCH<sub>2</sub>C(R) = CR 2, and Cp<sub>2</sub>TiCH<sub>2</sub>CHRCH<sub>2</sub> 3 with organic carbonyl compounds are explored. 1 with carbonyl, in a Wittig-type reaction, exchanges methylene for oxygen and yields alkenes; no intermediates can be observed. When treated with carbonyl, 2a (R = Ø) inserts O = C into the Ti-CH<sub>2</sub> bond, generating oxytitanacyclohexenes. Other metallacyclobutenes similarly insert carbonyl; or, if RC ≡ CR is labile, exchange methylene for oxygen, producing alkenes. 3a (R = t-butyl) with carbonyl compounds also exchanges methylene for oxygen, and the mechanism of this reaction is explored. 3a is in equilibrium with a titanocene-carbene-olefin complex 11, which is trapped by ketones. 11 is also in equilibrium with titanocene carbene 12 and free olefin; 12 is trapped by esters (as well as ketones}. The formation of 11 is rate-determining. Formation of 12 from 11, trapping of 11 by ketone, and the reverse reaction, formation of 3a from 11 are all competitive. Trapping of 12 by esters is competitive with the reverse reaction, formation of 11 from 12 and olefin. Relative rates of reaction of several ketones and esters are determined.</p> <p>A new platinum vinyl complex, L<sub>2</sub>Pt(CH = CH<sub>2</sub>) Me 3 (L = PMe<sub>2</sub>Ø) is prepared by treatment of the known L<sub>2</sub>Pt(CH = CH<sub>2</sub>)Cl with MeLi at low temperatures. Oxidative addition of MeI to the platinum (II) complex 3 generates L<sub>2</sub>Pt(CH = CH<sub>2</sub>)Me<sub>2</sub>I 4· The thermal decomposition of 4 is examined, and the relative amounts of ethane and propene formed lead to the conclusion that a vinyl group reductively eliminates twenty times faster than methyl.</p> <p>CpCr(NO)<sub>2</sub>Me is treated with various ligands in an attempt to see insertion of NO into the Cr-Me bond. A clean reaction is observed with PMe<sub>3</sub>. Instead of insertion, deoxygenation of NO by PMe<sub>3</sub> generates O = PMe<sub>3</sub> and, ultimately, CpCr(NO) (:NMe) - (PMe<sub>3</sub>) 5a· Similar reactions occur with CpCr(NO)<sub>2</sub>R, R = n-hexyl, isobutyl, Ø, Thermal decomposition of 5a or treatment with H<sup>+</sup> generates CH<sub>4</sub>.</p> 1981 Thesis NonPeerReviewed application/pdf en other https://thesis.library.caltech.edu/10749/1/Brown-Wensley_KA_1981.pdf Brown-Wensley, Katherine Ann (1981) Formation of Bonds to Carbon at Transition Metal Centers. Dissertation (Ph.D.), California Institute of Technology. doi:10.7907/sz44-eg97. https://resolver.caltech.edu/CaltechTHESIS:03022018-142501266 <https://resolver.caltech.edu/CaltechTHESIS:03022018-142501266> https://resolver.caltech.edu/CaltechTHESIS:03022018-142501266 CaltechTHESIS:03022018-142501266 10.7907/sz44-eg97
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description <p>The reactions of Cp<sub>2</sub>TiCH<sub>2</sub>Al(Me)<sub>2</sub>Cl 1, Cp<sub>2</sub>TiCH<sub>2</sub>C(R) = CR 2, and Cp<sub>2</sub>TiCH<sub>2</sub>CHRCH<sub>2</sub> 3 with organic carbonyl compounds are explored. 1 with carbonyl, in a Wittig-type reaction, exchanges methylene for oxygen and yields alkenes; no intermediates can be observed. When treated with carbonyl, 2a (R = Ø) inserts O = C into the Ti-CH<sub>2</sub> bond, generating oxytitanacyclohexenes. Other metallacyclobutenes similarly insert carbonyl; or, if RC ≡ CR is labile, exchange methylene for oxygen, producing alkenes. 3a (R = t-butyl) with carbonyl compounds also exchanges methylene for oxygen, and the mechanism of this reaction is explored. 3a is in equilibrium with a titanocene-carbene-olefin complex 11, which is trapped by ketones. 11 is also in equilibrium with titanocene carbene 12 and free olefin; 12 is trapped by esters (as well as ketones}. The formation of 11 is rate-determining. Formation of 12 from 11, trapping of 11 by ketone, and the reverse reaction, formation of 3a from 11 are all competitive. Trapping of 12 by esters is competitive with the reverse reaction, formation of 11 from 12 and olefin. Relative rates of reaction of several ketones and esters are determined.</p> <p>A new platinum vinyl complex, L<sub>2</sub>Pt(CH = CH<sub>2</sub>) Me 3 (L = PMe<sub>2</sub>Ø) is prepared by treatment of the known L<sub>2</sub>Pt(CH = CH<sub>2</sub>)Cl with MeLi at low temperatures. Oxidative addition of MeI to the platinum (II) complex 3 generates L<sub>2</sub>Pt(CH = CH<sub>2</sub>)Me<sub>2</sub>I 4· The thermal decomposition of 4 is examined, and the relative amounts of ethane and propene formed lead to the conclusion that a vinyl group reductively eliminates twenty times faster than methyl.</p> <p>CpCr(NO)<sub>2</sub>Me is treated with various ligands in an attempt to see insertion of NO into the Cr-Me bond. A clean reaction is observed with PMe<sub>3</sub>. Instead of insertion, deoxygenation of NO by PMe<sub>3</sub> generates O = PMe<sub>3</sub> and, ultimately, CpCr(NO) (:NMe) - (PMe<sub>3</sub>) 5a· Similar reactions occur with CpCr(NO)<sub>2</sub>R, R = n-hexyl, isobutyl, Ø, Thermal decomposition of 5a or treatment with H<sup>+</sup> generates CH<sub>4</sub>.</p>
author Brown-Wensley, Katherine Ann
spellingShingle Brown-Wensley, Katherine Ann
Formation of Bonds to Carbon at Transition Metal Centers
author_facet Brown-Wensley, Katherine Ann
author_sort Brown-Wensley, Katherine Ann
title Formation of Bonds to Carbon at Transition Metal Centers
title_short Formation of Bonds to Carbon at Transition Metal Centers
title_full Formation of Bonds to Carbon at Transition Metal Centers
title_fullStr Formation of Bonds to Carbon at Transition Metal Centers
title_full_unstemmed Formation of Bonds to Carbon at Transition Metal Centers
title_sort formation of bonds to carbon at transition metal centers
publishDate 1981
url https://thesis.library.caltech.edu/10749/1/Brown-Wensley_KA_1981.pdf
Brown-Wensley, Katherine Ann (1981) Formation of Bonds to Carbon at Transition Metal Centers. Dissertation (Ph.D.), California Institute of Technology. doi:10.7907/sz44-eg97. https://resolver.caltech.edu/CaltechTHESIS:03022018-142501266 <https://resolver.caltech.edu/CaltechTHESIS:03022018-142501266>
work_keys_str_mv AT brownwensleykatherineann formationofbondstocarbonattransitionmetalcenters
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