Competitive reactions stereoselectivity

It should be noted that the stereoselectivity is also completely different from that associated with triplet 1,4-biradicals. Thus, a highly exo-selective formation ofbicyclic oxetanes was observed during PET-promoted PB reactions, whereas a highly endo-selective formation ofbicyclic oxetanes was reported for PB reactions that proceeded via triplet 1,4-biradicals (see Scheme 7.25). The competitive reaction pathway for electron-rich alkenes explained a notable solvent effect on the regioselectivity and stereoselectivity of the PB reaction of dihydrofuran (Scheme 7.15). Thus, an endo-selective formation of 3-alkoxyoxetane was observed when using benzene, whereas the exo-isomer of 2-alkoxyoxetane was detected as a product of the PB reaction in acetonitrile (Scheme 7.15). 

Rhodium-based catalysis suffers from the high cost of the metal and quite often from a lack of stereoselectivity. This justifies the search for alternative catalysts. In this context, ruthenium-based catalysts look rather attractive nowadays, although still poorly documented. Recently, diruthenium(II,II) tetracarboxylates [42], polymeric and dimeric diruthenium(I,I) dicarboxylates [43], ruthenacarbor-ane clusters [44], and hydride and silyl ruthenium complexes [45 a] and Ru porphyrins [45 b] have been introduced as efficient cyclopropanation catalysts, superior to the Ru(II,III) complex Ru2(OAc)4Cl investigated earlier [7]. In terms of efficiency, electrophilicity, regio- and (partly) stereoselectivity, the most efficient ruthenium-based catalysts compare rather well with the rhodium(II) carboxylates. The ruthenium systems tested so far seem to display a slightly lower level of activity but are somewhat more discriminating in competitive reactions, which apparently could be due to the formation of less electrophilic carbenoid species. This point is probably related to the observation that some ruthenium complexes competitively catalyze both olefin cyclopropanation and olefin metathesis [46], which is at variance with what is observed with the rhodium catalysts. 

In order to characterize the nature of the oxygenating species formed in the reactions of H2O2, PhIO, MCPBA, and dioxygen plus aldehyde, we studied stereoselectivity in c/5-stilbene epoxidation, regioselectivity in (+)-limonene and norbornene epoxidations, and intermolecular competitive reactions between cyclohexene... 

When a mixture of diastereomers reacts with a chiral or achiral reagent, it involves two competitive reactions. The rate laws are very similar to the one estabhshed for the KR (see Section 2.1). The stereoselectivity factor is the relative rate constants of reaction of the two diastereomers. One of the two diastereomers will be destroyed more slowly than the other and will be recovered with some diastereomeric excess (de jj ) that increases with conversion. Equation 2.6 applies by replacing ee j by de j. ... 

Control of selectivity, chemo-, regio-, and stereoselectivity, is the most important problem in the hydroformylation reaction. As far as chemoselectivity is concerned such competitive reactions as isomerization, double bond hydrogenation and aldehyde hydrogenation occur under hydroformylation conditions. 

The stereoselectivity of an addition reaction is considerably lower when the reactions are conducted in polar solvents, complexing additives such as /V./V,A. A, -tetramethylethylenedi-arnine arc used, or when the stereogenic center carries a methoxy group instead of a hydroxy group. This behavior is explained as competition between the cyclic model and a dipolar model, proposed for carbonyl compounds bearing a polar substituent such as chlorine with a highly... 

Differences in chirality of substrate, and nature of solvent, have no effect on the competitive nature of the displacement of 0-alkyl and S-methyl groups in the reactions between (+)-pinacolyl alkoxide and 0-ethyl (and methyl) S-methyl methylphosphonothioates (Scheme 23). For the (R)-( + ) esters, e.g. (210), the displacements are highly stereoselective and occur with configurational inversion,but the enantiomeric esters do not display such stereoselectivity. (-)-Menthol might be considered a mirror image of (S)-pinacol, and similar reactions with the sodium salt of (-)-menthol occur highly stereoselectively... 

An interaction, E(n) - F(n ), stabilizing a concerted [2 -[ -2 0] reaction 79> could not be competitive because the magnitude of the interaction integral y would be too low. Experiments with substituted olefins in which the extent of stereoselectivity could be determined would be useful in shedding more light on this point. 

Toru has investigated the stereoselectivity of the conjugate addition of trialkylboranes to 2-arylsulfinylcyclopentenones. Excellent stereocontrol is achieved with different alkyl radicals (Scheme 27) [73-76]. In the acyclic series, the lack of diastereoselectivity in the addition step and a competitive Pummerer rearrangement have limited the synthetic potential of this reaction [77]. 

A study of debrominations of vtc-dibromides promoted by diaryl tellurides and din-hexyl telluride has established several key features of the elimination process the highly stereoselective reactions of e/7f/tro-dibromides are much more rapid than for fhreo-dibromides, to form trans- and cw-alkenes, respectively the reaction is accelerated in a more polar solvent, and by electron-donating substituents on the diaryl telluride or carbocation stabilizing substituents on the carbons bearing bromine. Alternative mechanistic interpretations of the reaction, which is of first-order dependence on both telluride and vtc-dibromide, have been considered. These have included involvement of TeAr2 in nucleophilic attack on carbon (with displacement of Br and formation of a telluronium intermediate), nucleophilic attack on bromine (concerted E2- k debromination) and abstraction of Br+ from an intermediate carbocation. These alternatives have been discounted in favour of a bromonium ion model (Scheme 9) in which the role of TeArs is to abstract Br+ in competition with reversal of the preequilibrium bromonium ion formation. The insensitivity of reaction rate to added LiBr suggests that the bromonium ion is tightly paired with Br. ... 

Reactions of propynyl alcohols and their derivatives with metal hydrides, such as lithium aluminum hydride, constitute an important regio- and stereoselective approach to chiral allenes of high enantiomeric purity63-69. Formally, a hydride is introduced by net 1,3-substitution, however, when leaving groups such as amines, sulfonates and tetrahydropyranyloxy are involved, it has been established that the reaction proceeds by successive trans-1,2-addition and preferred anti-1,2-elimination reactions. The conformational mobility of the intermediate results in both syn- and ami- 1,2-elimination, which leads to competition between overall syn- and anti-1,3-substitution and hence lower optical yields and/or a reversal of the stereochemistry. 

Section 2 discusses the syntheses of different classes of concave acids and bases. Convergent synthetic strategies were chosen for an easy structural variation of the reagents (modular assembly). Section 3 characterizes the concave acids and concave bases and checks whether the acid/base properties of the parent compounds benzoic acid, pyridine and 1,10-phenanthroline are conserved in the bimacrocyclic structures. In Section 4, the influence of the concave shielding on the reactivity and selectivity of the concave reagents is measured in model reactions. In principle, the concave shielding should be able to influence inter- and intramolecular competitions as well as chemoselectivity and (dia)stereoselectivity. If the reagent is chiral, enantioselectivity should also be observable. 

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