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Stereospecific ligand substitution

Specificity and Stereospecificity of Siderophore Recognition Probed by Metal and Ligand Substitution... [Pg.2346]

A detailed investigation of the stereochemistry of cis- and tran5-[RuCl2(L-L)2] (l L = o-QH< (EMePh)2 E = As, P) has been undertaken. The optically active, racemic, meso, syn, and anti forms of the trans compound were isolated for both ligands each of these subsequently isomerized to the corresponding cis complex by reaction with AlEts and the various diastereoisomers of the latter separated and characterized. Whereas the trans isomers are relatively inert, the cis complexes readily undergo stereospecific halogen substitution by 1 and A minor product obtained... [Pg.3834]

The ligand substitution reactions of square planar complexes of Pt(II) of the type PtA2XL are stereospecific. If the substrate is a cis-isomer, the product is invariably a cis-isomer and vice versa. The reaction occurs via trigonal bipyramidal intermediate, as shown in Figure 10. [Pg.167]

Besides ruthenium porphyrins (vide supra), several other ruthenium complexes were used as catalysts for asymmetric epoxidation and showed unique features 114,115 though enantioselectivity is moderate, some reactions are stereospecific and treats-olefins are better substrates for the epoxidation than are m-olcfins (Scheme 20).115 Epoxidation of conjugated olefins with the Ru (salen) (37) as catalyst was also found to proceed stereospecifically, with high enantioselectivity under photo-irradiation, irrespective of the olefmic substitution pattern (Scheme 21).116-118 Complex (37) itself is coordinatively saturated and catalytically inactive, but photo-irradiation promotes the dissociation of the apical nitrosyl ligand and makes the complex catalytically active. The wide scope of this epoxidation has been attributed to the unique structure of (37). Its salen ligand adopts a deeply folded and distorted conformation that allows the approach of an olefin of any substitution pattern to the intermediary oxo-Ru species.118 2,6-Dichloropyridine IV-oxide (DCPO) and tetramethylpyrazine /V. V -dioxide68 (TMPO) are oxidants of choice for this epoxidation. [Pg.222]

All evidence points to a kineticaUy controlled differentiation between enantiotopic protons, leading to a configurationally stable intermediate 150 , which is stereospecifically substituted with retention of the configuration. Experiments with the deuteriated substrate 149-D (D for H at N-CH2 in 149) and the results of kinetic smdies support this assumption . The ligand (—)-sparteine (11) in 150 contributes to enhanced configurational stability this can be concluded from the lithiodestannylation experiment shown in equation 34. [Pg.1086]

Substitution reactions allow for the introduction or change of functional groups but rely on the prior formation of the stereogenic center. The approach can allow for the correction of stereochemistry. Reactions of epoxides, and analogous systems such as cyclic sulfates, allow for 1,2-functionality to be set up in a stereospecific manner. Reactions of this type have been key to the applications of asymmetric oxidations. The use of chiral ligands for allylic substitutions does allow for the introduction of a new stereogenic center. With efficient catalysts now identified, it is surely just a matter of time before this methodology is used at scale. [Pg.438]

It was found that substituted cyclopentadienyltitanium trichloride, in a combination with methylaluminoxane, exhibited higher catalytic activity for syndiospecific polymerisation of styrene than CpTiCl3 [52,53]. The efficiency of half-sandwich titanocenes as methylaluminoxane-activated precatalysts for the syndiospecific polymerisation of styrene increases in the following order CpTi(OMe)3 < Me4(Me3Si)CpTi(OMe)3 < Cp Ti(OMe)3. Thus, electron-donating substituents on the cyclopentadienyl ligand lead to increased catalyst activity and stability, stereospecificity and polymer Mw. [Pg.255]

Electrophilic substitutions of alkenyl-, aryl-, and alkynylsilanes with heteroatom-stabilized cationic carbon species generated by the action of a Lewis or Brpnsted acid (acyl cation, oxocarbenium ion, etc.) provide powerful methods for carbon-carbon bond formation. Particularly, intramolecular reactions of alkenylsilanes with oxocarbenium and iminium ions are very valuable for stereoselective construction of cyclic ether and amine units.21-23 For example, the BFj OEt -promoted reaction of (E)- and (Z)-alkenylsilanes bearing an acetal moiety in the alkenyl ligand gives 2,6-disubstituted dihydropyrans in a stereospecific manner (Scheme l).23 Arylsilanes also can be utilized for a similar cyclization.24... [Pg.298]

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See also in sourсe #XX -- [ Pg.60 ]



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Ligand substitution

Substitution stereospecificity

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