Enolate anions reaction with acyl halides

Because of the contribution of structures such as the one on the right to the resonance hybrid, the a-carbon of an enamine is nucleophilic. However, an enamine is a much weaker nucleophile than an enolate anion. For it to react in the SN2 reaction, the alkyl halide electrophile must be very reactive (see Table 8.1). An enamine can also be used as a nucleophile in substitution reactions with acyl chlorides. The reactive electrophiles commonly used in reactions with enamines are ... 

In related studies carried out by Gladysz and coworkers, the anionic silyl complex [(CO)4FeSiMe3] was found to react relatively cleanly with acyl halides, producing silyl enol ethers. The reaction with acetyl bromide gives a 70% yield of acetaldehyde trimethylsilyl enol ether (equation 89). An observed intermediate in this reaction was the... 

Compound 58 clearly offers more possibilities for disconnection. Disconnections are available at or near the carbon atom bearing the OH group, but also at or near both carbonyl carbons. The larger number of functional groups leads to more choices. Does the chemistry of the alcohol, the aldehyde, or the ketone offer the best choice for a disconnection The chemistry of alcohols is associated with oxidation and reduction (Chapter 17, Section 17.2 Chapter 19, Sections 19.2,19.3.4,19.4.1), formation and reactions of alkoxides as nucleophiles (Chapter 11, Section 11.3.2) and as bases (Chapter 12, Section 12.1), and formation of esters (Chapter 20, Section 20.5). Alcohols are converted to alkyl halides (Chapter 11, Section 11.7). Aldehydes and ketones are formed by the oxidation of alcohols (Chapter 17, Section 17.2), are reduced to alcohols (Chapter 19, Sections 19.2, 19.3.4, 19.4.1), undergo acyl addition (Chapter 18, Sections 18.1-18.7), and participate in enolate anion reactions (Chapter 22, Sections 22.2, 22.4, 22.6). Based on these reactions, several disconnections are shown, but several more are possible. 

Enolate anions of esters, such as ethyl 3-oxobutanoate or diethyl propanedioate, react with aeyl halides or anhydrides to give acylation products. These reactions are carried out best using sodium hydride instead of sodium ethoxide for production of the enol salt, because then no alcohol is liberated to react with the acyl halide or anhydride ... 

The copper-mediated 1,4-addition of alkyl groups to a,P-unsaturated ketones affords regiochemically pure enolate anions (see also Section 7.5) which may be trapped at oxygen with silyl halides, acyl halides, or dialkylcarbonates to provide silyl enol ethers, enol acetates, or enol carbonates, respectively. These can be unmasked at a later stage by reaction with MeLi to regenerate the enolate for further elaboration. ... 

Sulfonylation of aroylmalonates gives enol derivatives (175) because sul-fonyl chlorides are even harder than acyl chlorides. The a-alkoxy-/3-oxosulfone anions form sulfonyl reductone derivatives on reaction with ClCHjOMe or aroyl chlorides (163). This behavior is in direct contrast to the C-alkylation with alkyl halides. 

This chapter will discuss carbanion-like reactions that utilize enolate anions. The acid-base reactions used to form enolate anions will be discussed. Formation of enolate anions from aldehyde, ketones, and esters will lead to substitution reactions, acyl addition reactions, and acyl substitution reactions. Several classical named reactions that arise from these three fundamental reactions of enolate anions are presented. In addition, phosphonium salts wiU be prepared from alkyl halides and converted to ylids, which react with aldehydes or ketones to form alkenes. These ylids are treated as phosphorus-stabilized car-banions in terms of their reactivity. 

The acyl addition and acyl substitution reactions of enolate anions presented in this chapter clearly show that enolate anions are nucleophiles. In Chapter 11 (Section 11.3), various nucleophiles reacted with primary and secondary alkyl halides via Sn2 reactions. Enolate anions also react with alkyl halides via 8 2 reactions in what is known as enolate alkylation. 

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