Nucleophilic aromatic substitution enantioselectivity

Miscellaneous PTC Reactions The field of PTC is constantly expanding toward the discovery of new enantioselective transformations. Indeed, more recent applications have demonstrated the capacity of chiral quaternary ammonium salts to catalyze a number of transformations, including the Neber rearrangement (Scheme 11.19a), ° the trifluoromethylation of carbonyl compounds (Scheme 11.19b), ° the Mannich reaction (Scheme 11.19c), and the nucleophilic aromatic substitution (SnAt)... 

Scheme 11.13 Regioselective and enantioselective nucleophilic aromatic substitution reactions.

Jorgensen developed a catalytic regioselective and enantioselective nucleophilic aromatic substitution reaction of activated aromatic compounds with 1,3-dicarbonyl compounds under phase-transfer conditions. This was crucial for obtaining the C-arylated product 61 predominantly with high enantioselectivity by replacing a benzyl with a benzoate group in the cinchona alkaloids-derived phase-transfer catalyst (Scheme 11.13) [49]. 

Recently, asymmetric PTC using chiral quaternary ammonium salt 110 has proven to be an effective method for the enantioselective a-arylation of a-imino acid derivatives 108 via asymmetric nucleophilic aromatic substitution, to give a,a-disubstituted a-amino acids 111 in good to high enantiomeric purity (Scheme 8.22) [86]. 

An enantioselective method in which a chiral catalyst is responsible of a desymmetrizing nucleophilic aromatic substitution through discrimination in the displacement of an enantiotopic leaving group has been reported very recently in the heterocyclic series. Under PTC conditions, the chiral counterion 113 (10% mol) directs the substitution of prochiral dichloropyrimidine 112 by PhSKby a tandem desymmetrization/kinetic resolution mechanism, leading to the chiral product 114 (Scheme 8.23) [87]. 

Scheme 10 Enantioselective nucleophilic aromatic substitution catalysed by bifunctional phosphonium salts.

Tomioka documented the use of organolithium reagents in enantioselec-tive conjugate additions to conjugated imines (Equation 31) [136]. The readily available chiral diether 173 served to mediate such additions with high asymmetric induction for example, the addition of PhLi to 172 furnished aldehyde 174 in 94% ee after hydrolysis of the imine adduct. In subsequent developments, Tomioka reported the enantioselective preparation of biaryls in which a naphthyllithium participates in a nucleophilic aromatic substitution catalyzed by only 5mol% of 173 (see insert on the left) and delivers the product in 82% ee [137]. 

Scheme 16. Comparison of TADDOL with BINOL and Future Goals. Derivatives of (R,R)-TADDOLs and of (P)- or (S)-BINOL, when employed in the same reaction, often give the same product enantiomer preferentially (cf. the Cj-symmetrical structural similarity). While TADDOLs are much easier to prepare and to modify, they are many orders of magnitude less acidic than BINOLs (TADDOLates are less polar ligands to a metal). Some TADDOL derivatives contain CPh2X groups which are labile to (undesired) nucleophilic substitution the dioxolane group of TADDOLs, on the other hand, is surprisingly stable to hydrolysis. BINOL (a naphthol derivative ) can be very sensitive to oxidation and (undesired) electrophilic aromatic substitution, and there are conditions under which it may racemize. Some goals to increase the usefulness of the TADDOL system are shown at the bottom of the Scheme other P derivatives, more acidic derivatives, reagents for enantioselective protonation, deprotonation,...

Replacement of one carbonyl group by phosphine (thus creating chirality at cobalt) has been shown to permit enantioselective addition of nucleophiles to the cations. Regioselectivity of aromatic substitution by the cations has been studied in resorcinol derivatives and examples of aromatic substitution extended to include indoles. ... 

As previously discussed, activation of the iridium-phosphoramidite catalyst before addition of the reagents allows less basic nitrogen nucleophiles to be used in iridium-catalyzed allylic substitution reactions [70, 88]. Arylamines, which do not react with allylic carbonates in the presence of the combination of LI and [Ir(COD)Cl]2 as catalyst, form allylic amination products in excellent yields and selectivities when catalyzed by complex la generated in sim (Scheme 15). The scope of the reactions of aromatic amines is broad. Electron-rich and electron-neutral aromatic amines react with allylic carbonates to form allylic amines in high yields and excellent regio- and enantioselectivities as do hindered orlAo-substituted aromatic amines. Electron-poor aromatic amines require higher catalyst loadings, and the products from reactions of these substrates are formed with lower yields and selectivities. 

Aldol reactions using a quaternary chinchona alkaloid-based ammonium salt as orga-nocatalyst Several quaternary ammonium salts derived from cinchona alkaloids have proven to be excellent organocatalysts for asymmetric nucleophilic substitutions, Michael reactions and other syntheses. As described in more detail in, e.g., Chapters 3 and 4, those salts act as chiral phase-transfer catalysts. It is, therefore, not surprising that catalysts of type 31 have been also applied in the asymmetric aldol reaction [65, 66], The aldol reactions were performed with the aromatic enolate 30a and benzaldehyde in the presence of ammonium fluoride salts derived from cinchonidine and cinchonine, respectively, as a phase-transfer catalyst (10 mol%). For example, in the presence of the cinchonine-derived catalyst 31 the desired product (S)-32a was formed in 65% yield (Scheme 6.16). The enantioselectivity, however, was low (39% ee) [65],... 

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