document2
DESCRIPTION
ahdudsaudashdsahdbdbndmTRANSCRIPT
17.517.5Reactions of Aldehydes and Reactions of Aldehydes and
Ketones:Ketones:A Review and a PreviewA Review and a Preview
Already covered in earlier chapters:Already covered in earlier chapters:
reduction of C=O to CHreduction of C=O to CH22
Clemmensen reductionClemmensen reduction
Wolff-Kishner reductionWolff-Kishner reduction
reduction of C=O to CHOHreduction of C=O to CHOH
addition of Grignard and organolithium reagentsaddition of Grignard and organolithium reagents
Table 17.2 Reactions of Aldehydes and KetonesTable 17.2 Reactions of Aldehydes and Ketones
17.617.6Principles of Nucleophilic Principles of Nucleophilic
Addition to Carbonyl Groups:Addition to Carbonyl Groups:Hydration of Aldehydes and Hydration of Aldehydes and
KetonesKetones
HH22OO
Hydration of Aldehydes and KetonesHydration of Aldehydes and Ketones
CC••••OO ••••
HOHO CC OO HH••••
••••
••••
••••
compared to Hcompared to H
electronic: electronic: alkyl groups stabilize alkyl groups stabilize reactantsreactants
steric: steric: alkyl groups crowdalkyl groups crowdproductproduct
OHOH
OHOH
RR R'R'++ HH22OO CCCCRR R'R'
OO
Substituent Effects on Hydration EquilibriaSubstituent Effects on Hydration Equilibria
C=OC=O hydratehydrate KK %% RelativeRelativeraterate
CHCH22=O=O CHCH22(OH)(OH)22 23002300 >99.9>99.9 22002200
CHCH33CH=OCH=O CHCH33CH(OH)CH(OH)22 1.01.0 5050 1.01.0
(CH(CH33))33CCH=OCCH=O (CH(CH33))33CCH(OH)CCH(OH)22 0.20.2 1717 0.090.09
(CH(CH33))22C=OC=O (CH(CH33))22C(OH)C(OH)22 0.00140.0014 0.140.14 0.00180.0018
Table 17.3 Equilibrium Constants and Relative RatesTable 17.3 Equilibrium Constants and Relative Ratesof Hydrationof Hydration
when carbonyl group is when carbonyl group is destabilizeddestabilized
•alkyl groups alkyl groups stabilizestabilize C=O C=O
•electron-withdrawing groups electron-withdrawing groups destabilizedestabilize C=O C=O
When does equilibrium favor hydrate?When does equilibrium favor hydrate?
OHOH
OHOH
RR RR++ HH22OO CCCCRR RR
OO
Substituent Effects on Hydration EquilibriaSubstituent Effects on Hydration Equilibria
RR = CH = CH33: : KK = 0.000025 = 0.000025
RR = CF = CF33: : KK = 22,000 = 22,000
Mechanism of Hydration (base)Mechanism of Hydration (base)
CC••••OO •••••••• OO ••••
HH
••••
––
Step 1:Step 1:
++
••••
HOHO CC OO••••
••••
••••••••––
Mechanism of Hydration (base)Mechanism of Hydration (base)
Step 2:Step 2:
••••OOHH
HH
••••
••••HOHO CC OO
••••
••••
••••••••––
++••••
••••OO
HH
••••––••••
HOHO CC OOHH••••
••••
••••
Mechanism of Hydration (acid)Mechanism of Hydration (acid)
CC••••OO ••••
Step 1:Step 1:
++ ••••
HH
OOHH
HH++
++
CC
••••OOHH++
•••• ••••
HH
OO
HH
Mechanism of Hydration (acid)Mechanism of Hydration (acid)
Step 2:Step 2:
CC••••OOHH++
++••••
HH
OO
HH
••••CC OOHH
••••
••••
HH
OO
HH
•••• ++
Mechanism of Hydration (acid)Mechanism of Hydration (acid)
Step 3:Step 3:
++••••
HH
OO
HH
••••CC OOHH
••••
HHOO
HH
••••
•••• •••• OO
HH
••••CC OOHH
••••
••••
++
HH
HHOO
HH ••••
++
17.7Cyanohydrin Formation
++
Cyanohydrin FormationCyanohydrin Formation
••••••••CC OO HCNHCN HHCC OONN CC••••
••••
••••
Cyanohydrin FormationCyanohydrin Formation
••••••••CC OO
CC––
NN•••• ••••
Cyanohydrin FormationCyanohydrin Formation
––OONN CC CC••••
•••• ••••••••
HH HH
HH++OO ••••
HH
HH
OO ••••••••OONN CC CC••••
•••••••• HH
2,4-Dichlorobenzaldehyde2,4-Dichlorobenzaldehydecyanohydrin (100%)cyanohydrin (100%)
ExampleExample
ClCl ClCl CHCH
OOClCl
ClCl CHCNCHCN
OHOHNaCN, waterNaCN, water
then Hthen H22SOSO44
ExampleExample
CHCH33CCHCCH33
OONaCN, waterNaCN, water
then Hthen H22SOSO44
CHCH33CCHCCH33
OHOH
CNCN
(77-78%)(77-78%)
Acetone cyanohydrin is used in the synthesis Acetone cyanohydrin is used in the synthesis of methacrylonitrile (see problem 17.7).of methacrylonitrile (see problem 17.7).