Metal complexes of ferrocenylphosphines : catalytic properties of some rhodium complexes
A series of achiral and chiral ferrocenylphosphines have been prepared with special emphasis on those containing bulky tert-butyl groups on phosphorus (I and V were previously known): [See Thesis for Diagrams] They form a number of transition metal complexes such as [Rh(L-L)-(NBD)]ClO₄ (L-L = I-VI...
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ndltd-UBC-oai-circle.library.ubc.ca-2429-255962018-01-05T17:43:11Z Metal complexes of ferrocenylphosphines : catalytic properties of some rhodium complexes Kim, Tae-Jeong A series of achiral and chiral ferrocenylphosphines have been prepared with special emphasis on those containing bulky tert-butyl groups on phosphorus (I and V were previously known): [See Thesis for Diagrams] They form a number of transition metal complexes such as [Rh(L-L)-(NBD)]ClO₄ (L-L = I-VII; NBD = norbornadiene), M(L-L)X₂ (M = Pd, Ni; L- L = I - IV; X = CI, Br), M(L-L)(CO) ₄ (M = Cr, Mo; L-L = I), and Fe[sub x](L-L)(CO) [sub y](x = 1 , y = 3, x = 2, y = 8, L-L =1). All these ligands and their metal complexes have been fully characterized by analytical and spectroscopic techniques. In a number of cases these results are confirmed by X-ray analyses. The configuration of VII proved to be, for example, (S,S) with regard to central and planar chirality rather than the expected (S,R) found for V and VI. The achiral Rh(I) complexes [Rh(L-L)(NBD)]ClO₄ (L-L = I-IV) are efficient catalyst precursors for the hydrogenation of a range of olefins (1 atm H₂, 30°C). The presence of bulky tert-butyl groups enhances reaction rates except when bulky olefins are the substrates. The chiral trisphosphine Rh(I) complex [Rh(L-L)(NBD)] ClO₄ (L-L = VII) is a very efficient catalyst precursor for the asymmetric hydrogenation of acylamino-cinnamic, acylaminoacrylic, and (E)-α-methylcinnamic acids, giving 91, 95, and 61% e.e., respectively. The chiral Rh(I) complex, where L-L = VI, is a relatively poor catalyst for asymmetric hydrogenation as compared with the other two complexes (L-L = V , VII). Here again the presence of tert-butyl groups increases the reaction rates, and the rates become greater as the number of tert-butyl groups increases. These results and other comparative hydrogenation studies are discussed and rationalized in terms of the steric (including ligand conformation) and electronic effects of the substi-tuents on the phosphorus atom(s). The reaction of H₂ with the hydrogenation catalyst precursor [Rh(L-L)-(NBD)] ClO₄ (L-L = II) in MeOH results in crystals which have the structure [(L-L)(H)Rh(μ-H)3Rh(H)(L-L)] ClO₄. When L-L = IV, the same reaction results in a similar rhodium hydride although the positions of the hydrogen atoms are not well established. A number of other hydrides, some fluxional, are also obtained in various solvents from the catalyst precursors [Rh(L-L)(NBD)]- ClO₄ (L-L = I-VII). Where possible these have been characterized on the basis of their NMR spectra. The implication of these results with respect to the mechanisms of catalytic hydrogenation is discussed. Science, Faculty of Chemistry, Department of Graduate 2010-06-12T16:07:42Z 2010-06-12T16:07:42Z 1984 Text Thesis/Dissertation http://hdl.handle.net/2429/25596 eng For non-commercial purposes only, such as research, private study and education. Additional conditions apply, see Terms of Use https://open.library.ubc.ca/terms_of_use. University of British Columbia |
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English |
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A series of achiral and chiral ferrocenylphosphines have been prepared with special emphasis on those containing bulky tert-butyl groups on phosphorus (I and V were previously known): [See Thesis for Diagrams]
They form a number of transition metal complexes such as [Rh(L-L)-(NBD)]ClO₄ (L-L = I-VII; NBD = norbornadiene), M(L-L)X₂ (M = Pd, Ni; L- L = I - IV; X = CI, Br), M(L-L)(CO) ₄ (M = Cr, Mo; L-L = I), and Fe[sub x](L-L)(CO) [sub y](x = 1 , y = 3, x = 2, y = 8, L-L =1). All these ligands and their metal complexes have been fully characterized by analytical and spectroscopic techniques. In a number of cases these results are confirmed by X-ray analyses. The configuration of VII proved to be, for example, (S,S) with regard to central and planar chirality rather than the expected (S,R) found for V and VI.
The achiral Rh(I) complexes [Rh(L-L)(NBD)]ClO₄ (L-L = I-IV) are efficient catalyst precursors for the hydrogenation of a range of olefins (1 atm H₂, 30°C). The presence of bulky tert-butyl groups enhances reaction rates except when bulky olefins are the substrates. The chiral trisphosphine Rh(I) complex [Rh(L-L)(NBD)] ClO₄ (L-L = VII) is a very efficient catalyst precursor for the asymmetric hydrogenation of acylamino-cinnamic, acylaminoacrylic, and (E)-α-methylcinnamic acids, giving 91, 95, and 61% e.e., respectively. The chiral Rh(I) complex, where L-L = VI, is a relatively poor catalyst for asymmetric hydrogenation as compared with the other two complexes (L-L = V , VII). Here again the presence of tert-butyl groups increases the reaction rates, and the rates become greater as the number of tert-butyl groups increases. These results and other comparative hydrogenation studies are discussed and rationalized in terms of the steric (including ligand conformation) and electronic effects of the substi-tuents on the phosphorus atom(s).
The reaction of H₂ with the hydrogenation catalyst precursor [Rh(L-L)-(NBD)] ClO₄ (L-L = II) in MeOH results in crystals which have the structure [(L-L)(H)Rh(μ-H)3Rh(H)(L-L)] ClO₄. When L-L = IV, the same reaction results in a similar rhodium hydride although the positions of the hydrogen atoms are not well established. A number of other hydrides, some fluxional, are also obtained in various solvents from the catalyst precursors [Rh(L-L)(NBD)]- ClO₄ (L-L = I-VII). Where possible these have been characterized on the basis of their NMR spectra. The implication of these results with respect to the mechanisms of catalytic hydrogenation is discussed. === Science, Faculty of === Chemistry, Department of === Graduate |
author |
Kim, Tae-Jeong |
spellingShingle |
Kim, Tae-Jeong Metal complexes of ferrocenylphosphines : catalytic properties of some rhodium complexes |
author_facet |
Kim, Tae-Jeong |
author_sort |
Kim, Tae-Jeong |
title |
Metal complexes of ferrocenylphosphines : catalytic properties of some rhodium complexes |
title_short |
Metal complexes of ferrocenylphosphines : catalytic properties of some rhodium complexes |
title_full |
Metal complexes of ferrocenylphosphines : catalytic properties of some rhodium complexes |
title_fullStr |
Metal complexes of ferrocenylphosphines : catalytic properties of some rhodium complexes |
title_full_unstemmed |
Metal complexes of ferrocenylphosphines : catalytic properties of some rhodium complexes |
title_sort |
metal complexes of ferrocenylphosphines : catalytic properties of some rhodium complexes |
publisher |
University of British Columbia |
publishDate |
2010 |
url |
http://hdl.handle.net/2429/25596 |
work_keys_str_mv |
AT kimtaejeong metalcomplexesofferrocenylphosphinescatalyticpropertiesofsomerhodiumcomplexes |
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1718592847372877824 |