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Chapter 15: α-Carbon Chemistry: Enols, Enolates, and Enamines Back To Chapter

15.34: Alkylation of β-Diester Enolates: Malonic Ester Synthesis

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Alkylation of β-Diester Enolates: Malonic Ester Synthesis

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15.33: Alkylation of β-Ketoester Enolates: Acetoacetic Ester Synthesis

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In malonic ester synthesis, β-diesters bearing acidic α protons in the presence of a base and an alkyl halide generate substituted acetic acids via alkylated malonic ester intermediates.

Initially, the base removes the α proton of the diester to generate a nucleophilic enolate ion that is highly stabilized by three resonance structures.

Alkylating the anionic carbon through an S_N2 mechanism produces an alkyl malonic ester intermediate. This undergoes hydrolysis followed by acidification to give the β-diacid.

The β-diacid, at high temperatures, undergoes a concerted process that expels CO₂ to produce an enol. This rapidly tautomerizes to the stable keto form of the substituted acetic acid.

As the reaction comprises the elimination of a single proton, the resulting acid is monosubstituted.

If, however, the monoalkylated intermediate is subjected to the second alkylation process, a disubstituted acid will result.

15.34: Alkylation of β-Diester Enolates: Malonic Ester Synthesis

Malonic ester synthesis is a method to obtain α substituted carboxylic acids from ꞵ-diesters such as diethyl malonate and alkyl halides.

The reaction proceeds via abstraction of the acidic α hydrogen from a ꞵ-diester to produce a doubly stabilized enolate ion. The nucleophilic enolate attacks the alkyl halide in an S_N2 manner to form an alkylated malonic ester intermediate with a new C–C bond. Further treating the intermediate with aqueous acid or base results in the hydrolysis of the two ester groups to give a 1,3-dicarboxylic acid. The resulting ꞵ-diacid is unstable at high temperatures and readily eliminates CO₂ through a cyclic six-membered transition state, forming an enol. The enol tautomerizes to its more stable keto form producing a monosubstituted carboxylic acid. However, a disubstituted carboxylic acid is achieved if the deprotonation and alkylation steps are repeated before hydrolysis and decarboxylation.

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Alkylation Î²-Diester Enolates Malonic Ester Synthesis Carboxylic Acids Diesters Diethyl Malonate Alkyl Halides Enolate Ion Nucleophilic Enolate SN2 Manner Alkylated Malonic Ester Intermediate C-C Bond Formation Hydrolysis Ester Groups 1,3-dicarboxylic Acid Unstable CO2 Elimination Cyclic Six-membered Transition State Enol Tautomerization Keto Form Monosubstituted Carboxylic Acid Disubstituted Carboxylic Acid

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