19.14 Mechanism of Acid-Catalyzed Esterification.

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19.1419.14

Mechanism of Acid-Catalyzed EsterificationMechanism of Acid-Catalyzed Esterification

Acid-catalyzed EsterificationAcid-catalyzed Esterification

++ CHCH33OOHH

COHCOH

OOHH++

++ HH22OO

CCOOCHCH33

Important fact: the Important fact: the oxygenoxygen of the alcohol is of the alcohol isincorporated into the ester as shown.incorporated into the ester as shown.

(also called Fischer esterification)(also called Fischer esterification)

The mechanism involves two stages: The mechanism involves two stages:

1)1) formation of tetrahedral intermediateformation of tetrahedral intermediate(3 steps)(3 steps)

2)2) dissociation of tetrahedral intermediate dissociation of tetrahedral intermediate (3 steps)(3 steps)

Mechanism of Fischer EsterificationMechanism of Fischer Esterification

The mechanism involves two stages: The mechanism involves two stages:

1)1) formation of tetrahedral intermediateformation of tetrahedral intermediate(3 steps)(3 steps)

2)2) dissociation of tetrahedral intermediate dissociation of tetrahedral intermediate (3 steps)(3 steps)

Mechanism of Fischer EsterificationMechanism of Fischer Esterification CC

OOCHCH33

tetrahedral intermediate in esterification tetrahedral intermediate in esterification of benzoic acid with methanolof benzoic acid with methanol

First stage: First stage: formation of tetrahedral intermediateformation of tetrahedral intermediateFirst stage: First stage: formation of tetrahedral intermediateformation of tetrahedral intermediate

OOCHCH33

++ CHCH33OOHH

COHCOH

methanol adds to the methanol adds to the carbonyl group of the carbonyl group of the carboxylic acidcarboxylic acid

the tetrahedral the tetrahedral intermediate is intermediate is analogous to a analogous to a hemiacetalhemiacetal

Second stage: Second stage: conversion of tetrahedralconversion of tetrahedralintermediate to esterintermediate to ester

OOCHCH33

++ HH22OO

HH++this stage corresponds this stage corresponds to an acid-catalyzed to an acid-catalyzed dehydrationdehydration

CCOOCHCH33

Mechanism of formationMechanism of formationofof

tetrahedral intermediatetetrahedral intermediate

Step 1Step 1Step 1Step 1 CC

•••• ••••

••••••••

OO ••••++HH

CHCH33

Step 1Step 1Step 1Step 1 CC

•••• ••••

••••••••

OO ••••++HH

CHCH33

••••

++ HH •••• OO ••••

CHCH33

Step 1Step 1Step 1Step 1

••••

carbonyl oxygen is carbonyl oxygen is protonated because protonated because cation produced is cation produced is stabilized by electron stabilized by electron delocalization delocalization (resonance)(resonance)

••••••••

••••

•••• OO ••••

CHCH33

••••

•••• OO ••••

CHCH33

••••••••

OO ••••++

CHCH33

•••• OO ••••

CHCH33

HH••••

••••••••

••••

OO ••••

CHCH33

•••• OO ••••

CHCH33

••••

••••••••

••••

OO ••••

CHCH33

++ OO ••••

CHCH33

••••

••••••••

••••

OO ••••

CHCH33

••••

Tetrahedral intermediateTetrahedral intermediatetoto

ester stageester stage

••••

••••••••

••••

OOCHCH33••••

••••

OO ••••

CHCH33

HH++••••

••••••••

••••

OO ••••

CHCH33

HH++••••

••••••••

••••

••••••••

••••

HH HH++ •••• OO ••••

CHCH33

••••

••••••••

••••

HH HH++

••••

••••••••

••••

HH HH++

OO••••HH HH••••

OHOH••••••••

••••

OHOH••••••••

••••

OHOH••••

••••

OO••••

••••

OO••••

HH CHCH33•••• ++OOHH CHCH33••••

OO••••

••••

Activation of carbonyl group by protonation of Activation of carbonyl group by protonation of carbonyl oxygencarbonyl oxygen

Nucleophilic addition of alcohol to carbonyl groupNucleophilic addition of alcohol to carbonyl groupforms tetrahedral intermediateforms tetrahedral intermediate

Elimination of water from tetrahedral intermediate Elimination of water from tetrahedral intermediate restores carbonyl grouprestores carbonyl group

Key Features of MechanismKey Features of Mechanism

19.1519.15

Intramolecular Ester Formation:Intramolecular Ester Formation:

LactonesLactones

Lactones are cyclic estersLactones are cyclic esters

Formed by intramolecular esterification in aFormed by intramolecular esterification in acompound that contains a hydroxyl group andcompound that contains a hydroxyl group anda carboxylic acid functiona carboxylic acid function

LactonesLactones

ExamplesExamples

HHOOCHCH22CHCH22CHCH22COHCOH

OO++ HH22OO

4-hydroxybutanoic acid4-hydroxybutanoic acid 4-butanolide4-butanolide

IUPAC nomenclature: replace the IUPAC nomenclature: replace the -oic acid -oic acid ending of the carboxylic acid by ending of the carboxylic acid by -olide-olide

identify the oxygenated carbon by numberidentify the oxygenated carbon by number

ExamplesExamples

HHOOCHCH22CHCH22CHCH22COHCOH

HHOOCHCH22CHCH22CHCH22CHCH22COHCOH

HH22OO

4-hydroxybutanoic acid4-hydroxybutanoic acid

5-hydroxypentanoic acid5-hydroxypentanoic acid

4-butanolide4-butanolide

5-pentanolide5-pentanolide

Common namesCommon names OO

-butyrolactone-butyrolactone -valerolactone-valerolactone

Ring size is designated by Greek letter Ring size is designated by Greek letter corresponding to oxygenated carboncorresponding to oxygenated carbon

A A lactone has a five-membered ring lactone has a five-membered ring

A A lactone has a six-membered ring lactone has a six-membered ring

Reactions designed to give hydroxy acids often Reactions designed to give hydroxy acids often yield the corresponding lactone, especially if theyield the corresponding lactone, especially if theresulting ring is 5- or 6-membered.resulting ring is 5- or 6-membered.

LactonesLactones

ExampleExample

5-hexanolide (78%)5-hexanolide (78%)

HH33CC

CHCH33CCHCCH22CHCH22CHCH22COHCOH

1. NaBH1. NaBH44

2. H2. H22O, HO, H++

ExampleExample

5-hexanolide (78%)5-hexanolide (78%)

via:via: OO

HH33CC

CHCH33CCHCCH22CHCH22CHCH22COHCOH

1. NaBH1. NaBH44

2. H2. H22O, HO, H++

CHCH33CHCHCHCH22CHCH22CHCH22COHCOH

OOOOHH

19.14 Mechanism of Acid-Catalyzed Esterification.

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