Chiral ligands asymmetric amplification

A series of chiral p-hydroxysulfoximine ligands have been synthesised by Bolm et al. and further investigated for the enantioselective conjugate addition of ZnEt2 to various chalcone derivatives. The most eiScient sulfoximine, depicted in Scheme 2.33, has allowed an enantioselectivity of up to 72% ee to be obtained. These authors assumed a nonmonomeric nature of the active species in solution, as suggested by the asymmetric amplification in the catalysis with a sulfoximine of a low optical purity. 

It may not be necessary to employ an optically pure chiral ligand (BINOL) for the preparation of the catalyst because a high degree of asymmetric amplification can be expected. 

Enantioselective conjugate addition of diethylzinc proceeds in the presence of №( ) complex104. Asymmetric amplification was observed in reactions using chiral ligand l156, 66157, 47107 and 3 (equation 38)109. 

Tanaka reported the synthesis of (/ )-muscone (10) by an enantioselective conjugate addition of chiral alkoxydimethylcuprate, which was prepared from chiral ercdo-3-[(l-methylpyrrol-2-yl)methylamino]-l,7,7-trimethylbicyclo[2.2.1]heptan-2-ol (9), methyllithium, and copper iodide (Scheme 9.7) [16]. In this reaction, convex deviation from a linear correlation was observed when the chiral ligand had a higher enantiopurity. This positive NLE was probably induced by the formation of a reactive homochiral dinuclear copper complex to give (R)-muscone. Rossitter also observed asymmetric amplification in a copper-catalyzed conjugate addition of methyl-... 

It was soon recognized that in specific cases of asymmetric synthesis the relation between the ee of a chiral auxiliary and the ee of the product can deviate from linearity [17,18,72 - 74]. These so-called nonlinear effects (NLE) in asymmetric synthesis, in which the achievable eeprod becomes higher than the eeaux> represent chiral amplification while the opposite case represents chiral depletion. A variety of NLE have been found in asymmetric syntheses involving the interaction between organometallic compounds and chiral ligands to form enantioselective catalysts [74]. NLE reflect the complexity of the reaction mechanism involved and are usually caused by the association between chiral molecules during the course of the reaction. This leads to the formation of diastereoisomeric species (e.g., homochiral and heterochiral dimers) with possibly different relative quantities due to distinct kinetics of formation and thermodynamic stabilities, and also because of different catalytic activities. 

In order to achieve an amplification of chirality, it requires that/> 1. If P = 0 (no meso catalyst) or g = 1 (same reactivity of meso and homochiral catalysts), then/= 1. The condition/> 1 is achieved for 1 + p > 1 + g ), or g < 1. Thus the necessary condition for asymmetric amplification in the above model is for the heterochiral or meso catalyst to be less reactive than the homochiral catalyst. If the meso catalyst is more reactive, then/< 1, and hence a negative nonlinear effect is observed. The size of the asymmetric amplification is regulated by the value off, which increases as K does. The more meso catalyst (of the lowest possible reactivity) there is, the higher will be eeproduct. This is well illustrated by computed curves in Scheme 11. The variation of eeproduct with eeaux is represented for various values of g (the relative reactivity of the meso complex) with K = 4 (corresponding to a statistical distribution of ligands Scheme 11, top). The variation in the relative amounts of the three complexes with eeaux is also represented for a statistical distribution of ligands (Scheme 11, bottom). 

The asymmetric amplification is a consequence of an in situ increase in the ee of the active catalyst, since racemic ligand is trapped in the unreactive or weakly reactive meso catalyst. In the reservoir effect a similar phenomenon occurs outside the catalytic cycle. Let us assume that part of the initial chiral ligand, characterized by eeaux, is diverted into a set of catalytically inactive complexes (Scheme 12). 

The use of enantiomerically impure chiral ligands can sometimes lead to products with significantly higher or lower enantiomeric excesses [42]. When there is increased enantioselection, such nonlinear effects have been termed asymmetric amplification. Asymmetric amplification has been noted for the hydroborating... 

Non-linear effects were discovered in 1986 [5]. They are now widely recognized in many catalytic reactions, and provide a useful tool for mechanistic investigations. Moreover, they can have some practical applications. For example, in the case of asymmetric amplification it is not necessary to perform a costly complete resolution of a chiral ligand if the reaction involves a strong (-i-)-NLE. The concept of non-linearity has been extended to mixtures of diastereomeric ligands (vide supra). Finally, asymmetric amplification is very useful in reactions which display asymmetric autocatalysis, giving high levels of enantioselectivity after initiation with a catalyst of very low ee. 

Organometallic compounds asymmetric catalysis, 11, 255 chiral auxiliaries, 266 enantioselectivity, 255 see also specific compounds Organozinc chemistry, 260 amino alcohols, 261, 355 chirality amplification, 273 efficiency origins, 273 ligand acceleration, 260 molecular structures, 276 reaction mechanism, 269 transition state models, 264 turnover-limiting step, 271 Orthohydroxylation, naphthol, 230 Osmium, olefin dihydroxylation, 150 Oxametallacycle intermediates, 150, 152 Oxazaborolidines, 134 Oxazoline, 356 Oxidation amines, 155 olefins, 137, 150 reduction, 5 sulfides, 155 Oxidative addition, 5 amine isomerization, 111 hydrogen molecule, 16 Oxidative dimerization, chiral phenols, 287 Oximes, borane reduction, 135 Oxindole alkylation, 338 Oxiranes, enantioselective synthesis, 137, 289, 326, 333, 349, 361 Oxonium polymerization, 332 Oxo process, 162 Oxovanadium complexes, 220 Oxygenation, C—H bonds, 149... 

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