Alkylation, enolate ions hydrogenation

Ethyl 3-oxobutanoate, commonly called ethyl acetoacetate or ace tome tic ester, is much like malonic ester in that its ct hydrogens are flanked by two carbonyl groups. It is therefore readily converted into its enolate ion, which can be alkylated by reaction with an alkyl halide. A second alkylation can also be carried out if desired, since acetoacetic ester has two acidic a hydrogens. 

The three-step sequence of 0) enolate ion formation, (2) alkylation, and (3) hydrolvsis/decarboxylation is applicable to all /Tketo esters with acidic a hydrogens, not just to acetoacetic ester itself. For example, cyclic /3-keto esters such as ethyl 2-oxocycIohexanecarboxylate can be alkylated and decarboxy-lated to give 2-substituted cyclohexanones. 

Alpha hydrogen atoms of carbonyl compounds are weakly acidic and can be removed by strong bases, such as lithium diisopropylamide (LDA), to yield nucleophilic enolate ions. The most important reaction of enolate ions is their Sn2 alkylation with alkyl halides. The malonic ester synthesis converts an alkyl halide into a carboxylic acid with the addition of two carbon atoms. Similarly, the acetoacetic ester synthesis converts an alkyl halide into a methyl ketone. In addition, many carbonyl compounds, including ketones, esters, and nitriles, can be directly alkylated by treatment with LDA and an alkyl halide. 

Polar protic solvents also possess a pronounced ability to separate ion pairs but are less favorable as solvents for enolate alkylation reactions because they coordinate to both the metal cation and the enolate ion. Solvation of the enolate anion occurs through hydrogen bonding. The solvated enolate is relatively less reactive because the hydrogen-bonded enolate must be disrupted during alkylation. Enolates generated in polar protic solvents such as water, alcohols, or ammonia are therefore less reactive than the same enolate in a polar aprotic solvent such as DMSO. 

This section deals with the alkylation reactions of such enolates. In the presence of strong bases, amides carrying at least one a-hydrogen 1 can be deprotonated to form enolate ions which, on subsequent alkylation, give alkylated amides. Further reaction, e g., hydrolysis or reduction, furnishes the corresponding acids or primary alcohols, respectively. The pKa values for deprotonation are typically around 35 (extrapolated value DMSO3 7) unless electron-withdrawing substituents are present in the a-position. Thus, deprotonation usually requires non-nucleophilic bases such as lithium diisopropylamide (extrapolated 8 pKa for the amine in DMSO is around 44) or sodium hexamethyldisilazanide. 

We have seen many reactions where nucleophiles attack unhindered alkyl halides and tosylates by the SN2 mechanism. An enolate ion can serve as the nucleophile, becoming alkylated in the process. Because the enolate has two nucleophilic sites (the oxygen and the a carbon), it can react at either of these sites. The reaction usually takes place primarily at the a carbon, forming a new C—C bond. In effect, this is a type of a substitution, with an alkyl group substituting for an a hydrogen. 

Diethyl propanedioate, commonly called diethyl malonate or malonic ester, is more acidic than monocarbonyl compounds pK =13) because its a hydrogens are flanked by two carbonyl groups. Thus, malonic ester is easih converted into its enolate ion by reaction with sodium ethoxide in ethanol. The enolate ion, in turn, is a good nucleophile that reacts rapidh with an alkyl halide to give an a-substituted malonic ester. Note in the following examples that the abbreviation "Et" is used for an ethyl group, CH2CH3. 

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