Organic Chemistry, 6th Edition L. G. Wade, Jr. Chapter 22 Alpha Substitution and Condensations of Enols and Enolate Ions Jo Blackburn Richland College, Dallas, TX Dallas County Community College District ã 2006, Prentice Hall
Alpha Substitution Replacement of a hydrogen on the carbon adjacent to the carbonyl, C=O. => Chapter 22
Condensation with Aldehyde or Ketone Enolate ion attacks a C=O and the alkoxide is protonated. The net result is addition. => Chapter 22
Condensation with Esters Loss of alkoxide ion results in nucleophilic acyl substitution. => Chapter 22
Keto-Enol Tautomers Tautomers are isomers which differ in the placement of a hydrogen. One may be converted to the other. In base: => Chapter 22
Keto-Enol Tautomers (2) Tautomerism is also catalyzed by acid. In acid: => Chapter 22
Equilibrium Amounts For aldehydes and ketones, the keto form is greatly favored at equilibrium. An enantiomer with an enolizable hydrogen can form a racemic mixture. => Chapter 22
Acidity of -Hydrogens pKa for -H of aldehyde or ketone ~20. Much more acidic than alkane or alkene (pKa > 40) or alkyne (pKa = 25). Less acidic than water (pKa = 15.7) or alcohol (pKa = 16-19). In the presence of hydroxide or alkoxide ions, only a small amount of enolate ion is present at equilibrium. => Chapter 22
Enolate Reaction As enolate ion reacts with the electrophile, the equilibrium shifts to produce more. => Chapter 22
Acid-Base Reaction to Form Enolate Very strong base is required for complete reaction. Example: => Chapter 22
Halogenation Base-promoted halogenation of ketone. Base is consumed. Other products are water and chloride ion. => Chapter 22
Multiple Halogenations The -halo ketone produced is more reactive than ketone. Enolate ion stabilized by e--withdrawing halogen. => Chapter 22
Haloform Reaction Methyl ketones replace all three H’s with halogen. The trihalo ketone then reacts with hydroxide ion to give carboxylic acid. Iodoform, yellow ppt. => Chapter 22
Positive Iodoform for Alcohols If the iodine oxidizes the alcohol to a methyl ketone, the alcohol will give a positive iodoform test. => Chapter 22
Acid Catalyzed Halogenation of Ketones Can halogenate only one or two -H’s. Use acetic acid as solvent and catalyst. => Chapter 22
Aldehydes and Halogens Halogens are good oxidizing agents and aldehydes are easily oxidized. => Chapter 22
The HVZ Reaction The Hell-Volhard-Zelinsky reaction replaces the -H of a carboxylic acid with Br. => Chapter 22
Alkylation Enolate ion can be a nucleophile. Reacts with unhindered halide or tosylate via SN2 mechanism. => Chapter 22
Stork Reaction Milder alkylation method than using LDA. Ketone + 2 amine enamine. Enamine is -alkylated, then hydrolyzed. => Chapter 22
Acylation via Enamines Product is a -diketone. => Chapter 22
Aldol Condensation Enolate ion adds to C=O of aldehyde or ketone. Product is a -hydroxy aldehyde or ketone. Aldol may lose water to form C=C. => Chapter 22
Mechanism for Aldol Condensation => Also catalyzed by acid. Chapter 22
Dehydration of Aldol Creates a new C=C bond. => Chapter 22
Crossed Aldol Condensations Two different carbonyl compounds. Only one should have an alpha H. => Chapter 22
Aldol Cyclizations 1,4-diketone forms cyclopentenone. 1,5-diketone forms cyclohexenone. => Chapter 22
Planning Aldol Syntheses => Chapter 22
Claisen Condensation Two esters combine to form a -keto ester. => Chapter 22
Dieckmann Condensation A 1,6 diester cyclic (5) -keto ester. A 1,7 diester cyclic (6) -keto ester. => Chapter 22
Crossed Claisen Two different esters can be used, but one ester should have no hydrogens. Useful esters are benzoates, formates, carbonates, and oxalates. Ketones (pKa = 20) may also react with an ester to form a -diketone. => Chapter 22
-Dicarbonyl Compounds More acidic than alcohols. Easily deprotonated by alkoxide ions and alkylated or acylated. At the end of the synthesis, hydrolysis removes one of the carboxyl groups. acetoacetic ester, pKa =11 => malonic ester, pKa = 13 Chapter 22
Malonic Ester Synthesis Deprotonate, then alkylate with good SN2 substrate. (May do twice.) Decarboxylation then produces a mono- or di-substituted acetic acid. => Chapter 22
Acetoacetic Acid Synthesis Product is mono- or di-substituted ketone. => Chapter 22
Conjugate Additions When C=C is conjugated with C=O, 1,2-addition or 1,4-addition may occur. A 1,4-addition of an enolate ion is called the Michael reaction. => Chapter 22
Michael Reagents Michael donors: enolate ions stabilized by two electron-withdrawing groups. -diketone, -keto ester, enamine, -keto nitrile, -nitro ketone. Michael acceptors: C=C conjugated with carbonyl, cyano, or nitro group. conjugated aldehyde, ketone, ester, amide, nitrile, or a nitroethylene. => Chapter 22
A Michael Reaction Enolates can react with ,-unsaturated compounds to give a 1,5-diketo product. => -keto acid Chapter 22
Robinson Annulation A Michael reaction to form a -diketone followed by an intramolecular aldol condensation to form a cyclohexenone. => Chapter 22
Mechanism for Robinson Annulation (1) => Chapter 22
Mechanism for Robinson Annulation (2) => Chapter 22
End of Chapter 22 Chapter 22