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Chapter 13 Substitution Alpha to Carbonyl Groups

Chapter 13 Substitution Alpha to Carbonyl Groups. Formation and Reactions of Enolate Anions and Enols Alkylation of Ketones and Esters: S N 2 Reaction with Alkyl Halides Aldol Reaction, Aldol Condensation and Related Reactions: Nucleophilic Addition of Enolate Anions to Carbonyl Groups

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Chapter 13 Substitution Alpha to Carbonyl Groups

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  1. Chapter 13Substitution Alpha to Carbonyl Groups • Formation and Reactions of Enolate Anions and Enols • Alkylation of Ketones and Esters: SN2 Reaction with Alkyl Halides • Aldol Reaction, Aldol Condensation and Related Reactions: Nucleophilic Addition of Enolate Anions to Carbonyl Groups • The Claisen Condensation and Related Reactions: Acylation of Esters • Alkylation of -Dicarbonyl Compounds • Synthetic Methods • Spectroscopy

  2. Chapter 13Substitution Alpha to Carbonyl Groups • Formation and Reactions of Enolate Anions and Enols • Molecular Orbitals of Enolate Anions • Structure of Enolate Anions • Protonation of Enolate Anions • Halogenation Alpha to Carbonyl Groups • Iodoform Test • Kinetic versus Thermodynamic Deprotonation of Carbonyl Groups • Kinetic Control with Lithium diisopropyl amide (LDA) strong Base, poor Nucelophile

  3. Chapter 13Substitution Alpha to Carbonyl Groups • Alkylation of Ketones and Esters: SN2 Reaction with Alkyl Halides • Works best with primary halide or secondary halide, but not tertiary • More later in the chapter with -ketocarbonyls

  4. Chapter 13Substitution Alpha to Carbonyl Groups • Aldol Reaction, Aldol Condensation and Related Reactions: Nucleophilic Addition of Enolate Anions to Carbonyl Groups. • The Aldol Reaction (typically at low [base]) • The Aldol Condensation (at high [base] and high temp) • Aldol Reaction and Aldol Condensation of Ketones • Intramolecular Aldol Reaction and Aldol Condensation • Crossed Aldol Reaction • Nucleophilic Addition of ,-Unsaturated Carbonyl Groups: Conjugate Addition • Michael addition (Enolate reacts with ,-unsaturated carbonyl) • Robinson Annulation (two steps-Michael and Aldol condensation) • “Fun in Bases”

  5. Chapter 13Substitution Alpha to Carbonyl Groups • The Claisen Condensation and Related Reactions: Acylation of Esters The Aldol Reaction • The Claisen Condensation • Enolate formation, addition, elimination, deprotonation, protonation • forms -ketoester • The Dieckmann Condensation • Cyclic Claisen used to form 5 & 6 membered rings • same 5 steps as Claisen • Crossed Claisen Condensation • Enolate anion reacts with ester or carbonate ester or oxalate ester or benzoate ester • The Reformatsky Reaction • Enolate anion formed from -halo carbonyl followed by addition to carbonyl and hydrolysis

  6. Chapter 13Substitution Alpha to Carbonyl Groups • Alkylation of -Dicarbonyl Compounds • -Dicarbonyl Compounds • highly acidic, resonance stabilized • Alkylation of -Ketoesters • via SN2 displacement, can form mono and disubstituted • Alkylation of Malonic Acid Diesters • similar to -Ketoesters • Hydrolysis and Decarboxylation of -Ketoesters and Malonic Acid Diesters • Ester hydrolyzed to carboxylic acid, heat to eliminate CO2 • Acetoacetic Ester and Malonic Ester Synthesis • Synthetic utility: first do mono- or disubstituted alkylation, then hydrolyze and decarboxylate to the more substituted ketone. • Formation of Carbocyclic Rings using the Acetoacetic Ester and Malonic Ester Syntheses • with di-bromo alkyl, can form carbocyclic ring via intramolecular closure

  7. Chapter 13Substitution Alpha to Carbonyl Groups • Synthetic Methods • Review Table 13.1 p 692-693 • Using Enolate Anions and Enols to Introduce Various Functional Groups • Spectroscopy • Review of Reactions • Summary

  8. Chapter 13 Summary • Carbonyl enhances the acidity of hydrogen on -carbon • Treatment with base forms enolate anion, species with significant nucleophilic character • Under kinetic control conditions (e.g., LDA -Lithium di-isopropyl amide) the less stable enolate forms • Under thermodynamic equilibrium conditions (e.g., with hydroxide) the more substituted enolate anion will form. • Enolate anions (and enols) are nucleophiles which react with electrophiles including halogen, alkyl halides, ketones, aldehydes and esters • Enolate intermediates in Aldol, Aldol condensation, Michael reaction, Robinson Annulation, Claisen and Dieckmann and Reformatsky reactions

  9. Chapter 13 Summary • Nucelophiles can add 1,2 or 1,4 to ,-unsaturated carbonyls • Grignard and alkyllithium reagents add 1,2 • Enolate anions add 1,4 • Aldol and Claisen are valuable synthetic tools for the construction of carbon-carbon bonds between carbonyl groups. • Dieckmann condensation and Robinson annulation form 5 and 6 membered rings intramolecularly. • Hydrolysis and Decarboxylation of corresponding acetoacetic and malonic diesters are useful synthetic steps for substituted ketones and carboxylic acids.

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