Zinc ketone enolates Reformatsky reagent

The Reformatsky reagents, i.e. zinc enolates of esters, undergo Ni catalysed cross-coupling with aryl halides.53 The Ni catalysed reaction of arylzincs with a-bromoacetates also permits a-arylation of esters54 (Scheme 11.13). However, a-alkenylation of enolates of ketones, aldehydes, and esters has been less satisfactory. Its further development is clearly desirable. Alternatively, a-alkenylation of a-iodoenones in conjunction with conjugate reduction discussed earlier should be considered. 

The insight that zinc ester enolates can be prepared prior to the addition of the electrophile has largely expanded the scope of the Reformatsky reaction.1-3 Substrates such as azomethines that quaternize in the presence of a-halo-esters do react without incident under these two-step conditions.23 The same holds true for acyl halides which readily decompose on exposure to zinc dust, but react properly with preformed zinc ester enolates in the presence of catalytic amounts of Pd(0) complexes.24 Alkylations of Reformatsky reagents are usually difficult to achieve and proceed only with the most reactive agents such as methyl iodide or benzyl halides.25 However, zinc ester enolates can be cross-coupled with aryl- and alkenyl halides or -triflates, respectively, in the presence of transition metal catalysts in a Negishi-type reaction.26 Table 14.2 compiles a few selected examples of Reformatsky reactions with electrophiles other than aldehydes or ketones.27... 

Spectroscopic and crystallographic studies of Reformatsky reagents derived from a-halo esters showed that the enoiate is present in the C-enolate form and in ether solvents they form dimers. Enolates derived from a-halo ketones prefer the O-metal enoiate form. It is assumed, based on theoretical calculation, that the zinc enoiate dimers are dissociated by the action of the carbonyl compound and converted to the corresponding O-zinc enolates. Subsequently, the reaction goes through six-membered chairlike transition state. 

The Reformatsky reaction is the reaction of an a-halo ester with an aldehyde or ketone in the presence of zinc metal as shown in Scheme 1. The usual product of the reaction is a -hydroxy ester, which may be dehydrated in subsequent steps to give an unsaturated ester. A zinc ester enolate (1), the so-called Reformatsky reagent, is an intermediate in the reaction and the sequence is thus classified as an aldol condensation. Compared to the usual base-promoted aldol procedures, the distinguishing features of the Reformatsky reaction are the use of a metal-halogen redox reaction rather than an acid-base reaction to form the enolate, and the fact that the counterion of the enolate is zinc. 

This chapter summarizes studies on the nature of the Reformatsky reagent as well as other, related, zinc enolates and outlines the synthetic aspects of the reaction with aldehydes and ketones. In addition, reactions of the Reformatsky reagent with imines and nitriles (the Blaise reaction) are described. 

In 1887, the Russian chemist Sergei Reformatsky at the University of Kiev discovered that treatment of an a-haloester with zinc metal in the presence of an aldehyde or a ketone followed by hydrolysis in aqueous acid results in formation of a /3-hydroxyester. This reaction is similar to a Grignard reaction in that a key intermediate is an organo-metallic compound, in this case, a zinc salt of an ester enolate anion. Grignard reagents, however, are so reactive that they undergo self-condensation with the ester. 

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