Electrophilic reactions diethylzincs

More recently, an improved methodology for the preparation of secondary organozincs was introduced by Marek, Knochel and coworkers13. Reaction of a 1,1-diiodoalkane 24 with diethylzinc (1.2 equivalents) at —50 °C in a mixture of THF and N-methylpyrrolidi-none (NMP) and warming to room temperature produced a new secondary organozinc 26 which could be trapped with various electrophiles to give a range of compounds 27 (equation 11). 

An example for the use of the boron-zinc exchange reaction for copper-mediated SN2 -substitutions of allylic electrophiles is the hydroboration of nitroolefin 130 with diethylborane, followed by successive transmetallation of the borane 131 with diethylzinc and CuCN-2LiCl, and final trapping with allyl bromide to give the product 133 with 83% yield over four steps (Scheme 34).34,34a This transformation again demonstrates the tolerance of the method towards functional groups and acidic hydrogen atoms. 

The authors discovered a remarkable improvement of the Simmons-Smith reaction by using diethylzinc instead of zinc-copper couple 155, 159, 160, 162, 234a, 373, 518a). Reaction (8) is electrophilic and proceeds... 

The research on asymmetric organozinc additions to carbonyl compounds started in 1984 when Oguni and Omi obtained 49% e.e. in the reaction of diethylzinc with benzaldehyde catalyzed by (X)-leucinol. Since then, a huge number of chiral (see Chiral) catalysts, mostly derived from amino alcohols, have been developed and the subject has been extensively reviewed. 63.264 jjjg highly enantioselective (see Electrophile) ligand (—)-3-exo-dimethylaminoisobomeol [(-)-DAIB] developed by Noyori and coworkers in 1986 is still used even if its application is mostly limited to aromatic and heteroaromatic aldehydes (equation 62). As shown by previous studies, chiral (see Chiral) ligands have a dual... 

The Simmons-Smith reaction is an efficient and powerful method for synthesizing cyclopropanes from alkenes [43]. Allylic alcohols are reactive and widely used as substrates, whereas a,j8-unsaturated carbonyl compounds are unreactive. In 1988, Ambler and Davies [44] reported the electrophilic addition of methylene to a,/3-unsaturated acyl ligands attached to the chiral-at-metal iron complex. The reaction of the racemic iron complex 60 with diethylzinc and diiodomethane in the presence of ZnCl2 afforded the c/s-cyclopropane derivatives 61a and 61b in 93 % yield in 24 1 ratio (Sch. 24). 

A large number of chiral a,a -orz/zo-disubstituted diphenyldiselenides with hydroxy and amino functions (e.g., 244 and 245) have been prepared by Wirth and co-workers. They were used as electrophiles for a number of asymmetric addition and cyclization reactions including the total synthesis of the lignan derivatives (-l-)-samin and (-l-)-membrine as well as catalysts in the asymmetric diethylzinc addition to aldehydes. 

Using this exchange reaction, some functionalizations of aryl halides were examined. As an example of 1,2-addition to a carbonyl group, the arylzinc prepared from 4-iodobenzoate and diethylzinc in the presence of Bu-P4 base in THF was reacted with benzaldehyde to give the benzhydrol derivative in 78% yield. As for the 1,4-addition reaction, the arylzinc prepared similarly in THF was reacted with chalcone and the 1,4-adduct was obtained in 71% yield under copper-free reaction conditions. Allylation was also carried out in the absence of copper additive, and allylbenzoate was obtained in 98% yield. It has been reported that arylzinc compounds are inert to 1,4-addition and allylation reaction in the absence of additives and conventionally the employment of copper species has been widely used. However, in this case the Bu-P4 base is considered to promote the reactivity of arylzinc compounds toward electrophiles [59] (Scheme 5.38). 

The addition of a chiral allenyl metal to an aldehyde generating a 2-substituted butynyl structure is named Marshall-Tamaru MT) reaction (Scheme 5-13). An allenyl palladium species is generated via a formal Sn2 substitution of the mesylate, which in turn undergoes a transmetalation with diethylzinc yielding a nucleophilic species (Scheme 5-13). The reaction of the electrophile proceeds via a similar -ester enolate transition state as depicted in Scheme 5-13. Corresponding allenylindium reagents can also be used instead of allenylzinc intermediates. ... 

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