Reactions Systems Chiral

The H4 system is the prototype for many four-elecbon reactions [34]. The basic tetrahedral sfructure of the conical intersection is preserved in all four-electron systems. It arises from the fact that the four electrons are contributed by four different atoms. Obviously, the tefrahedron is in general not a perfect one. This result was found computationally for many systems (see, e.g., [37]). Robb and co-workers [38] showed that the structure shown (a tetraradicaloid conical intersection) was found for many different photochemical transformations. Having the form of a tetrahedron, the conical intersection can exist in two enantiomeric structures. However, this feature is important only when chiral reactions are discussed. 

An achiral reagent cannot distinguish between these two faces. In a complex with a chiral reagent, however, the two (phantom ligand) electron pairs are in different (enantiotopic) environments. The two complexes are therefore diastereomeric and are formed and react at different rates. Two reaction systems that have been used successfully for enantioselective formation of sulfoxides are illustrated below. In the first example, the Ti(0-i-Pr)4-f-BuOOH-diethyl tartrate reagent is chiral by virtue of the presence of the chiral tartrate ester in the reactive complex. With simple aryl methyl sulfides, up to 90% enantiomeric purity of the product is obtained. 

The first reductive kinetic resolution of racemic sulphoxides was reported by Balenovic and Bregant. They found that L-cysteine reacted with racemic sulphoxides to produce a mixture of L-cystine, sulphide and non-reduced optically active starting sulphoxide (equation 147). Mikojajczyk and Para reported that the reaction of optically active phosphonothioic acid 268 with racemic sulphoxides used in a 1 2 ratio gave the non-reduced optically active sulphoxides, however, with a low optical purity (equation 148). It is interesting to note that a clear relationship was found between the chirality of the reducing P-thioacid 268 and the recovered sulphoxide. Partial asymmetric reduction of racemic sulphoxides also occurs when a complex of LiAlH with chiral alcohols , as well as a mixture of formamidine sulphinic acid with chiral amines, are used as chiral reducing systems. ... 

An overview of the catalytically active M-L systems is presented in terms of both achiral and chiral reactions. Where deemed appropriate, reference is also made to organometallic and organolanthanide catalysts, as well as (briefly) H—X addition to C=0. 

Many examples of asymmetric reactions catalyzed by copper complexes with chiral ligand systems have been reported. In particular, various copper-bis(oxazoline) catalysts (e.g., complexes (H) to (L), Scheme 48) are effective for carbon-carbon bond-forming reactions such as aldol,204 Mukaiyama-Michael, Diels-Alder,206 hetero Diels-Alder,207,208 dipolar cycloaddition,209,210... 

Bayardon and Sinou have reported the synthesis of chiral bisoxazolines, which also proved to be active ligands in the asymmetric allylic alkylation of l,3-diphenylprop-2-enyl acetate, as well as cyclopropanation, allylic oxidations and Diels-Alder reactions. [62] The ligands do not have a fluorine content greater than 60 wt% and so are not entirely preferentially soluble in fluorous solvents, which may lead to a significant ligand loss in the reaction system and in fact, all recycling attempts were unsuccessful. However, the catalytic results achieved were comparable with those obtained with their non-fluorous analogues. 

Table 34.8 Typical ranges of reaction conditions, optical yields, turnover frequencies (TOF) and substratexatalyst ratios (SCR) for the hydrogenation of C = N functions using various chiral catalytic systems.

The asymmetric alkylation of a carbonyl group is one of the most commonly used chirality transfer reactions. The chirality of a substrate can be transferred to the newly formed asymmetric carbon atom through this process. In surveying chiral enolate systems as a class of nucleophile, three general subdivisions can be made in such asymmetric nucleophilic addition reactions intra-annular, extra-annular, and chelation enforced intra-annular. 

Chiral Hydrazone Systems. In 1976, Corey and Enders34 demonstrated the great synthetic potential of metalated dimethylhydrazones as highly reactive intermediates in regio- and diastereoselective C C bond formation reactions. The procedure for carrying out the electrophilic substitution reaction... 

The hetero Diels-Alder reactions discussed thus far use 2-10 mol% of catalyst. Jorgensen s group44b found that the reaction could be carried out even at very low catalyst loading. The catalyst can conveniently be prepared in situ by mixing the chiral ligand 83 and copper triflate in the reaction system. Scheme 5-35 shows that product 112 can be obtained with good yield and high enan-... 

The self-assembly of a chiral Ti catalyst can be achieved by using the achiral precursor Ti(OPr )4 and two different chiral diol components, (R)-BINOL and (R,R)-TADDOL, in a molar ratio of 1 1 1. The components of less basic (R)-BINOL and the relatively more basic (R,R)-TADDOL assemble with Ti(OPr )4 in a molar ratio of 1 1 1, yielding chiral titanium catalyst 118 in the reaction system. In the asymmetric catalysis of the carbonyl-ene reaction, 118 is not only the most enantioselective catalyst but also the most stable and the exclusively formed species in the reaction system. 

Chirality element enumeration is essential for the classification of stereoselective reactions 27>. For instance, in order to distinguish an asymmetrically induced synthesis from other reactions whose stereoselectivity is also due to a chiral reference system, one must compare the number of chirality elements in the starting materials and the products. 

Polymerization that proceeds in an unsymmetrical manner in terms of chirality under the influence of chiral features present in one or more components of the reaction system. 

Sulfides are generally oxidized much faster than alkenes, and in the presence of excess oxidant further oxidation to the sulfone occurs. In the cases where the reaction is conducted in an asymmetric way, the chiral catalytic system may react faster with one enantiomeric sulfoxide to form the sulfone than with the other, so that kinetic resolution of the primarily formed sulfoxide may occur. In general, the reaction is carried out with alkyl hydroperoxides like TBHP in the presence of a metal catalyst like Mo, W, Ti or V complexes. In some cases the sulfoxidation with hydroperoxides can take place without the need of a metal catalyst. Both examples will be discussed in the following. 

Takemoto and his co-workers developed asymmetric allylic alkylation of allylic phosphates with (diphenyl-iminolglycinates as carbon-centered nucleophiles (Equation (56))/" " In this reaction system, use of optically active bidentate phosphites 142 bearing an (ethylthio)ethyl group as chiral ligands promotes the allylic alkylation, and chiral /3-substituted a-amino acids are obtained with an excellent enantioslectivity. 

In 2001, Takahashi and his co-workers developed the first asymmetric ruthenium-catalyzed allylic alkylation of allylic carbonates with sodium malonates which gave the corresponding alkylated compounds with an excellent enantioselectivity (Equation (Sy)). Use of planar-chiral cyclopentadienylruthenium complexes 143 with an anchor phosphine moiety is essential to promote this asymmetric allylic alkylation efficiently. The substituents at the 4-position of the cyclopentadienyl ring play a crucial role in controlling the stereochemistry. A kinetic resolution of racemic allylic carbonates has been achieved in the same reaction system (up to 99% ee). ... 

Hallberg and his co-workers reported in 1999 the first microwave-promoted asymmetric palladium-catalyzed allylic alkylation of acyclic and cyclic allylic esters with dimethyl malonate, using some chiral ligands 57 and 118 (Equations (65) and (55))3 s,l6Sa,i6Sb both cases, microwave irradiation reduces reaction time without any loss of enantio-selectivity. The same group successfully applied this reaction system to the molybdenum-catalyzed allylic alkylation (Equation ((,7)) 60.160 -l60. 

The enzymatic synthesis of chiral cyanohydrins has reached a high stage of development. The different reaction systems give the possibility to convert a great... 

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