A library of the enol and enolate mediated carbonyl compound reactions:

Intermolecular -alkylationand acetoacetic and malonic ester

synthesisvia enolate anions

Chapters 22 and 23

Intermolecular -halogenationand haloform reaction

via enols and enolate anionsChapters 22

O

O

CH3X

Intramolecular -alkylationFavorskii rearrangement

via enolate anionsextra

O

O

XX2

O

X

OH-

CH3O-

CO2H

CO2CH3

A library of the enol and enolate mediated carbonyl compound reactions:

Self-condensationSelf and mixed Aldol and Claisen

via enols and enolate anionsChapter 23

H

O

OH-OH

H

O

H

O

OH-

H

O

H

O

+

OCH3

O

OH-O

OCH3

O

OCH2CH3

O

OH-

H3CH2CO

O

OCH2CH3

O

H3CH2CO OCH2CH3

O

+

A library of the enol and enolate mediated carbonyl compound reactions:

Intramolecular condensationDieckmann

via enolate anionsChapter 23

OH-

OO

O

O

O

CO2Et

The α Position The carbon next to the carbonyl group is designated

as being in the α position Electrophilic substitution occurs at this position

through either an enol or enolate ion

Enols and enolate anions behave as nucleophiles and react with electrophiles because the double bonds are electron-rich compared to alkenes

Part A: Keto–Enol Tautomerism A carbonyl compound with a hydrogen atom on its a carbon rapidly

equilibrates with its corresponding enol Compounds that differ only by the position of a moveable proton are

called tautomers The enol tautomer is usually present to a very small extent and cannot

be isolated, but is formed rapidly, and serves as a reaction intermediate

1H-NMR spectrum of neat 2,4-pentanedione

O O O OH

2.22 ppm3.61 ppm 5.52 ppm 2.05 ppm

Acid Catalysis of Enolization Brønsted acids catalyze keto-enol tautomerization by

protonating the carbonyl and activating the α protons

Base Catalysis of Enolization Brønsted bases

catalyze keto-enol tautomerization

The hydrogens on the α carbon are weakly acidic and transfer to water is slow

In the reverse direction there is also a barrier to the addition of the proton from water to enolate carbon

General Mechanism of Addition to Enols

When an enol reacts with an electrophile the intermediate cation immediately loses the -OH proton to give an -substituted carbonyl compound.

O

H

O

O

O

-Halogenation of Aldehydes and Ketones

Aldehydes and ketones can be halogenated at their α positions by reaction with Cl2, Br2, or I2 in either the acidic or basic solutions.

Mechanism of Acid-Catalyzed Electrophilic

Substitution

O

CF3CO2H

O

Br

O

+ HO2CCF3

O

H

+ CF3CO2-

1.

2.

C

O

H

H

HH

+ CF3CO2-

fast

fastC

O

H

H

H

+ CF3CO2H

enol

Mechanism of Acid-Catalyzed Electrophilic Substitution

OH

+ Br Br

slowCH2Br

OH

+ Br

3.

CH2Br

O

H

+ Brfast

Br

O

+ HBr

4.

α-Bromoketones Undergo Facile Elimination Reaction to Yield α,-unsaturated Carbonyl Compounds for 1,4-addition Reactions.

-Bromination of Carboxylic Acids:The Hell–Volhard–Zelinskii Reaction

Carboxylic acids do not react with Br2.

Unlike aldehydes and ketones, they are brominated by a mixture of Br2 and PBr3

Mechanism of the Hell–Volhard–Zelinskii Reaction

PBr3 converts -CO2H to –COBr, which can enolize and add Br2

Part B: Enolate Ion Formation

Carbonyl compounds can act as weak acids (pKa of acetone = 19.3; pKa of ethane = 60)

The conjugate base of a ketone or aldehyde is an enolate ion - the negative charge is delocalized onto oxygen

Two Reactions Sites on Enolates Reaction on oxygen yields an enol derivative Reaction on carbon yields an -substituted carbonyl

compound

Reagents for Enolate Formation Ketones are weaker acids than the OH of alcohols but can be deprotonated

to a small extent by an alkoxide anion (RO-) to form the enolate. This is sufficient in reactions with strong electrophiles such as Br2.

Sodium hydride (NaH) or lithium diisopropylamide [LiN(i-C3H7)2] are strong enough to form large amounts of the enolates required for -alkylation reactions.

LDA is generated from butyllithium (BuLi) and diisopropylamine (pKa = 40) and is soluble in organic solvents.

Mechanism of Base-Promoted Electrophilic Halogenation

1. The base abstracts the -H from the keto tautomer.

2. The resulting enolate anion reacts with an electrophile.O

O

XBr2

CH3O-Na+

Mechanism

C

O O

H

CH3O-

H

HH H

+ CH3OHfast

O

H

H

+Br Br

slow

O

Br

+ Br-

The Haloform Reaction

Base-promoted reaction occurs through an enolate anion intermediate. Monohalogenated products are themselves rapidly turned into enolate

anions and further halogenated until the trihalo compound is formed from a methyl ketone.

The product is cleaved by hydroxide with -CX3 as a leaving group.

-Alkylation of Enolate Ions via Lithium Enolate Salts

Even unreactive ketones will be easily deprotonated with LDA to give stable, isolable lithium enolate salts.

-Alkylation of Enolate Ions Alkylation occurs when the nucleophilic enolate ion reacts with the

electrophilic alkyl halide or tosylate and displaces the leaving group

SN2 reaction:, the leaving group X can be chloride, bromide, iodide, or tosylate R should be primary or methyl and preferably should be allylic or benzylic Secondary halides react poorly, and tertiary halides don't react at all because of

competing elimination

Mechanism of Base-Promoted Electrophilic Alkylation

2. CH3OTs

1. THF / [(CH3)2CH]2N-Li+

Mechanism

O O

HH

H+

fast

+H3C OTs

slow

+ OTs-Li+

O O

Li+

[(CH3)2CH]2NH[(CH3)2CH]2N-

O

H

Li+ O

O

+ BrCH2CH CH2LDA

THF

O

1.

CH2

O

H + N fast

O

+ NH

2.O

Br CH2

C

H

C

H

H

O

++ Br

allylic

allylic bromide

Intramolecular -alkylation reaction: Favorskii rearrangement.

Intramolecular -alkylation in the Favorskii rearrangement proceeds via enolate anion generated within the molecule. The molecule must contain a leaving group, usually a halide. The purpose of the reaction is two fold: 1. Molecular rearrangements of ketones to carboxylic acids and 2. Ring contraction reaction to make high energy small size and/or fused rings.

O

X

OH-

CH3O-

CO2H

CO2CH3

12 3 4

5

5

4

3

21

O

BrOH-

CO2H

H H

+

O

Br

H

O

Br

H

O

Br-+

O

OH-+

OHO

OHOH2O

CO2H

OH-+

Mechanism

Intramolecular -alkylation reaction: Favorskii rearrangement resulting in ring contractions.

O

Br

OH-

CO2H

1

2 3 4

55

4

3

21

6 6

O

Br

CH3O-CO2CH3

O

BrH

HCH3O

fastCH3OH +

O

Br

O

Brslow

O

+ Br

O

+ CH3Oslow

OCH3O

OCH3O

fast

OCH3

O+ CH3OH

fast

COCH3O

1.

2.

3.

4. 5.

β-Dicarbonyls Are More Acidic

When a hydrogen atom is flanked by two carbonyl groups, its acidity is enhanced (Table 22.1)

Negative charge of enolate delocalizes over both carbonyl groups

Relative acidities are dictated by the substituents on the carbonyl group.

H

O

O

OCH3

O

O

OCH3

O

H3CH2CO

O

OCH2CH3

O

O O

OCH3

O

17 19 25pKa

acidity reduced due to theinductive effect of the alkyl group

acidity reduced due to theresonance effect of the alkoxy group

pKa 19 9 19 11 13

Ethyl Acetoacetate Ester

O

OCH2CH3

O

H3CH2CO

O

OCH2CH3

O

pKa 19 11 13

Diethyl Malonate Ester

Acetoacetic and malonic esters are easily converted into the corresponding enolate anions by reaction with sodium ethoxide in ethanol. The enolates are good nucleophiles that react rapidly with alkyl halides to give an -substituted derivatives. The product has an acidic α-hydrogen, allowing the alkylation process to be repeated.

Formation of Enolate and Alkylation

Formation of Enolate and Alkylation

2. The Malonic Ester Synthesis

For preparing a carboxylic acid from an alkyl halide while lengthening the carbon chain by two atoms

3. The Acetoacetic Ester Synthesis

Overall: converts an alkyl halide into a methyl ketone

Synthesis of ketones using acetoacetic ester via the decarboxylation of acetoacetic acid

-Ketoacid from hydrolysis of ester undergoes decarboxylation to yield a ketone via the enol

The malonic ester synthesis converts an alkyl halide into a carboxylic acid while lengthening the carbon chain by two atoms

Synthesis of carboxylic acids using malonic ester via the decarboxylation of malonic acid

Decarboxylation of -Ketoacids

Decarboxylation requires a carbonyl group two atoms away from the β CO2H

The second carbonyl permit delocalization of the resulting enol The reaction can be rationalized by an internal acid-base reaction

Generalization: -Keto Esters The sequence: enolate ion formation, alkylation,

hydrolysis/decarboxylation is applicable to -keto esters in general

Cyclic -keto esters give 2-substituted cyclohexanones

Preparation Cycloalkane Carboxylic Acids

1,4-dibromobutane reacts twice, giving a cyclic product Three-, four-, five-, and six-membered rings can be prepared

in this way