3. Metal hydride reduction (NaBH4 and LiAlH4)
The most common sources of the hydride Nucleophile are lithium aluminum hydride
(LiAlH4) and sodium borohydride (NaBH4).
The hydride anion is not present during this reaction; rather, these reagents serve as a
source of hydride due to the presence of a polar metal-hydrogen bond
Because aluminium is less electronegative than boron, the Al-H bond in LiAlH4 is
more polar, thereby, making LiAlH4 a stronger reducing agent.
Addition of a hydride anion (H:-) to an aldehyde or ketone gives an alkoxide anion,
which on protonation yields the corresponding alcohol .
Aldehydes produce 1°-alcohols and ketones produce 2°-alcohols.
Al
H
H H
H
Li B
H
H H
H
Na H
R.C.P.KASEGAON
4. Metal hydride reduction by LiAlH4 and NaBH4
R C
O
H
LiAlH4
R C
H
OH
H LiOH
+ + AlH3
R C
O
H
NaBH4
R C
H
OH
H NaCl
+ + BH3
HCl
2
H O
R.C.P.KASEGAON
5. Mechanism of Metal hydride reduction by LiAlH4
R C
O
H + Al
H
H
H
H
Li R C
O
H
H
Li+
+ AlH3
1. Nucleophilic attack by hydride
2.Protonation of Alkoxide ion
R C
O
H
H
Li+
+ H OH R C
OH
H
H
+ LiOH
R.C.P.KASEGAON
6. Mechanism of Metal hydride reduction by NaBH4
R C
O
H + B
H
H
H
H
Na R C
O
H
H
Na+
+ BH3
1. Nucleophilic attack by hydride
2.Protonation of Alkoxide ion
R C
O
H
H
Na+
+ H Cl R C
OH
H
H
+ NaCl
R.C.P.KASEGAON
7. Examples of Metal hydride reduction by LiAlH4&bNaBH4
O
H
LiAlH4
H3C C
H
OH
H LiOH
+ + AlH3
O
H
NaBH4
H3C C
H
H NaCl
+ + BH3
HCl
2
H O
H3C C
acetaldehyde
H3C C
acetaldehyde ethanol
ethanol
OH
H3C C
O
CH3
LiAlH4
H3C C
H
OH
LiOH + AlH3
H3C C
O
CH3
NaBH4
H3C C
H
CH3 NaCl + BH3
HCl
2
H O
Acetone
acetone
CH3
+
+
propan-2-ol
OH
propan-2-ol
R.C.P.KASEGAON
8. Application
1. Aldehydes are converted into primary alcohol(Alcohol preparation)
2. Ketones are converted into secondary alcohol (Alcohol Preparation)
3. Identification Class of alcohol
R.C.P.KASEGAON
10. INTRODUCTION
4
This reaction was first reported by Clemmensen of
Park Davis in 1913.
It is the reduction of carbonyl groups ( in
aldehyde and ketone) to methylene group.
This reaction done with zinc amalgam and hydrochloric
acid and it is generally known as Clemmensen reduction.
The Clemmensen reduction is particularly effective at reducing aryl-
alkyl ketones,such as those formed in a Friedel-Crafts acylation.
R.C.P.KASEGAON
14. APPLICATIONS
🠶 This reaction has widely used to convert a carbonyl group into a
methylene group.
🠶 Also important application in the preparation of polycyclic
aromatics and aromatics containing unbranched side
hydrocarbon chains.
🠶 To reduce aliphatic and mixed aliphatic-aromatic carbonyl
compounds
8
R.C.P.KASEGAON
16. Birch Reduction
The reduction of aromatic substrates with alkali metals, alcohol in liquid
ammonia is known as "Birch reduction
This reaction is named after a Australian chemist Sir Arthur John Birch.
The Birch reduction is an organic reaction where
aromatic rings undergo a
1,4-reduction to provide unconjugated cyclohexadienes .
The reduction is conducted by sodium or lithium metal in liquid ammonia
and in the presence of an alcohol.
R.C.P.KASEGAON
17. Birch Reduction
The mechanism begins with a Single Electron Transfer (SET) from the
metal to the aromatic ring, forming a radical anion.
The anion then picks up a proton from the alcohol which results in a neutral
radical intermediate.
Another SET, and abstraction of a proton from the alcohol results in the
final cyclohexadiene product and two equivalents of metal alkoxide salt as a
by-product.
R.C.P.KASEGAON
19. Mechanism of Birch Reduction
2Na+
e-
2e-
H
H
H
HO CH3
2 Na NH3
H H
H
H
e-
H
H
HO CH3
H
H H
-CH3O
H
-CH3O
H
O + 2Na
2 CH3 2CH3ONa
R.C.P.KASEGAON
20. Application of Birch Reduction
1) Naphthalene can be reduced to 1,4,5,8-tetrahydronaphthalene by
using Birch reduction conditions.
Na, NH3(Liq)-78°C
EtOH, Et2O
1,4,5,8-tetrahydronaphthalene
2) In the birch reduction of benzoic acid, the protonation occurs at ipso and para
positions
relative to -COOH group on the benzene ring.
COOH
Na, NH3
C2H5OH
COOH
cyclohexa-2,5-dienecarboxylic acid
benzoic acid R.C.P.KASEGAON
22. Kishner
INTRODUCTION
The Wolff– Kishner reduction was discovered independently by N.
in 1911 and L. Wolff in 1912.
TheWolff–Kishner reduction is a reaction used in organic chemistry to
convert carbonyl functionalities into methylene groups.
The Wolff-Kishner reduction is an organic reaction used to convert an
aldehyde or ketone to an alkane using hydrazine, base, and thermal
conditions
Because the Wolff–Kishner reduction requires highly basic conditions, it is
unsuitable for base-sensitive substrates.
R.C.P.KASEGAON
26. MODIFICATION
🠶 The reaction has been extensively modified.
🠶 One of the modification uses the Huang Minlon modification
using distillation to remove excess water and also used 85% hydrazine
and solvent used is ethylene glycol.
🠶 In addition, the Wolff- kishner reduction has been carried out in
DMSO instead of hydroxylic solvent by addition of hydrazones into
anhydrous DMSO containing freshly sublimed potassium tert-
butoxide at 250C.
🠶 Moreover,it has been reported that the Wolff-Kishner reduction
can occur in a very short period of time in a microwave irradiation,
affording product with high purity.
13
R.C.P.KASEGAON
27. APPLICATIONS
🠶 This reaction has very broad application in organic synthesis,
especially for the multiwalled carbon nanotubes.
🠶 In 2011, Pettus and Green reduced a tricyclic carbonyl compound
using the Huang Minlon modification of the Wolff–Kishner
reduction.Several attempts towards decarbonylation of tricyclic allylic
acetate containing ketone failed and the acetate functionality had to be
removed to allow successful Wolff–Kishner reduction. Finally, the
allylic alcohol was installed via oxyplumbation.
🠶 The Wolff–Kishner reduction has also been used on kilogram scale
for the synthesis of a functionalized imidazole substrate.
14
R.C.P.KASEGAON
29. INTRODUCTION
Named after Rupert Viktor Oppenauer.
It is a gentle method for selectively oxidizing secondary alcohols to
ketones.
The reaction is the opposite of Meerwein– Ponndorf –Verley reduction.
The alcohol is oxidized with aluminium isopropoxide in excess
acetone.
This shifts the equilibrium toward the product side.
R.C.P.KASEGAON
30. The oxidation is highly selective for secondary alcohols and does not
oxidize other sensitive functional groups such as amines and sulfides,
Though primary alcohols can be oxidized under Oppenauer conditions,
primary alcohols are seldom oxidized by this method due to the
competing aldol condensation of aldehyde products.
The Oppenauer oxidation is still used for the oxidation of acid labile
substrates.
Cont……
R.C.P.KASEGAON
33. MODIFICATION
Woodward modification
🠶 In the Woodward modification, Woodward substituted potassium
tert- butoxide for the aluminium alkoxide.
🠶 The Woodward modification of the Oppenauer oxidation is used
when certain alcohol groups do not oxidize under the standard
Oppenauer reaction conditions.
🠶 For example, Woodward used potassium tert-butoxide
and benzophenone for the oxidation of quinine to quininone, as the
traditional aluminium catalytic system failed to oxidize quinine due
to the complex formed by coordination of the Lewis- basic nitrogen
to the aluminium centre.
28
R.C.P.KASEGAON
34. Cont……
Other modifications
•Several modified aluminium alkoxide catalysts have been also reported
•For example, a highly active aluminium catalyst was reported by Maruoka and
co-workers which was utilized in the oxidation of carveol to carvone (a member
of a family of chemicals called terpenoids) in excellent yield (94%)
29
R.C.P.KASEGAON
36. APPLICATIONS
The Oppenauer oxidation is used to prepare analgesics in the
pharmaceutical industry such as morphine and codeine. For
instance, codeinone is prepared by the Oppenauer oxidation
of codeine.
R.C.P.KASEGAON
37. Cont……
The Oppenauer oxidation is also used to synthesize hormones.
Progesterone is prepared by the Oppenauer oxidation of
pregnenolone.
R.C.P.KASEGAON
39. 6. Dakin Reaction
Dakin Reaction is the replacement of the aldehyde group of ortho and para hydroxy and
ortho amino-benzaldehyde (or ketone) by a hydroxyl group on reaction with alkaline
hydrogen peroxide.
H2O2
NaOH
OH
C
O
H
OH
OH
+ H-COOH
Catechol
Salicylic acid
R.C.P.KASEGAON
40. 6. Dakin Reaction- Mechanism
NaOH +
OH Na
OH-
HO OH H2O
OH O
HO O
C H
O OH
OH O
C H
O OH
Na
-NaOH
OH
O
O
C H
H-OH
OH
OH
Catechol
+ HCOOH
salicylic acid
1 2.
3.
R.C.P.KASEGAON
41. Applications of Dakin oxidation reaction
1. Synthesis of Pyrro gallol mono methyl ether- Anesthetic agent
2. Synthesis of Hydroquinone-Treatment of acne
3. Phenol preparation
CHO
OH
H2O2
NaOH, H2O
OCH3
OH
OH
OCH3
2,3 Dihydroxy anisole
(Pyrrogallol monomethyl ether)
C OH
CH3
H2O2
2
NaOH, H O
HO OH
O
p-hydroxyacetophenone Hydroquinone
-2-hydroxy, 3-3methoxy
benzaldehyde
R.C.P.KASEGAON
42. Beckmann rearrangement
• The acid-catalysed conversion of ketoximes to amides is known as
the Beckmann rearrangement
• The Beckmann rearrangement, named after the German chemist
Ernst Otto Beckmann (1853–1923)
• This rearrangement is occurs in both cyclic and acyclic
compoun
ds
.
• Aldoximes are less reactive.
• Cyclic oximes yield lactams and acyclic oximes yield amides
2
R.C.P.KASEGAON
44. Reaction mechanism
The first step in the process is formation of an oxime from the aldehyde or
ketone,
4
4
R.C.P.KASEGAON
45. Reaction mechanism
This rearrangement take place an alkyl migration with expulsion of the
hydroxyl group to form a nitrilium ion followed by hydrolysis.
4
5
R.C.P.KASEGAON
46. Migratory aptitude
• The relative migratory aptitudes of different groups in Beckmann rearrangement
is illustrated below.
4
6
R.C.P.KASEGAON
47. Applications in drug synthesis:-
• An alternative industrial synthesis method for Paracetamol. It is involves direct
acylation of phenol with acetic anhydride catalyzed by HF, conversion of the
ketone to a ketoxime with hydroxylamine, followed by the acid-catalyzed
Beckmann Rearrangement to give the amide
7
Paracetamol
R.C.P.KASEGAON
48. 4
8
Applications in drug synthesis:-
• The Beckmann rearrangement is also used in the
synthesi
s of
1. DHEA
2. Benazepril
3. Etazepine etc.
R.C.P.KASEGAON
49. Applications in polymer synthesis:-
• Beckmann rearrangement can be rendered catalytic using cyanuric chloride and
zinc chloride as a co-catalyst. For
example, cyclododecanone can be converted to the
correspondi
ng lactam,
the monomer used in the production of Nylon 12
4
9
R.C.P.KASEGAON
50. Applications in polymer synthesis:-
• The Beckmann rearrangement is also used in the
synthesis of Nylon 6
5
0
R.C.P.KASEGAON
51. Schmidt Rearrangement
The Schmidt reaction is an organic reaction in which an azide reacts with a carbonyl derivative, usually an aldehyde, ketone, or
carboxylic acid, under acidic conditions to give an amine or amide, with expulsion of nitrogen.
The reaction is superior to the Curtius or Hofmann rearrangement because it directly converts an acid or ester to amine, without
making the acid derivatives.
The reaction is limited to acid insensitive compounds.
The reaction is effective with carboxylic acids to give amines, and with ketones to give amides.
R.C.P.KASEGAON
53. The reaction proceeds with faster rate with sterically hindered acids which forms acyl cation in presence of acids, even
without heating.
Acids that do not form acyl cation react through the protonation of the acid under heating, as shown previously.
acyl cation
Crowding around the center of the “R” group facilitates the formation of acyl cation, thus enhances the rate.
R.C.P.KASEGAON
56. (A)
(B)
(6)
Evidence for the carbocation intermediate formation
Formation of the carbocation step (6) in Schmidt reaction can be evidenced by the formation of the tetrazole (A) and
the substituted urea (B), which are often isolated from the reaction medium when excess of azide is used. These
products are obtained from the intermediate carbocation as the amide does not react with hydrogen azide in the
reaction condition.
Unsymmetrical ketone gives a mixture of two product
R.C.P.KASEGAON
57. Application of Schmidt Rearrangement
1. Preparation of Primary Amines
COOH
3
H C +NH3
H2SO4
NH2
H3C
Toludine
Tolueic acid
+ NH3
H2SO4
2. Preparation of Capro-lactams and polymerisation of caprolactam with base to form nylone
O
O
NH
Lactam
Cyclohexanone
R.C.P.KASEGAON
58. Application of Schmidt Rearrangement
3. Synthesis of Acetanilide from acetophenone- Analgesic, Antirhuematic
4. Synthesis of Benzanilide from Benzophenone- Perfume and dye
C
O
CH3
+ NH3
H2SO4
acetophenone
NH C
O
CH3
Acetanilide
C
O
+ NH3
H2SO4
NH C
O
benzophenone
Benzanilide
R.C.P.KASEGAON
59. Claisen–Schmidt Condensation Reaction
The reaction between an aldehyde or ketone having an alpha-hydrogen with an
aromatic carbonyl compound lacking an alpha hydrogen is called the Claisen–
Schmidt condensation.
In cases where the product formed still has reactive alpha hydrogen and a hydroxide
adjacent to an aromatic ring, the reaction will quickly undergo dehydration leading to the
condensation product
C
O
H
+ CH3
C
O
CH3
NaOH, Aq. EtOH
H
C CH
C
O
C
H
H
C
Dibenzal acetone
Benzaldehyde
2
R.C.P.KASEGAON
62. Application
1. A reaction employed for preparation of unsaturated aldehydes and ketones
by condensation of aromatic aldehydes with aliphatic aldehyde or ketone in presence of
sodium hydroxide. E.g. synthesis of cinnamaldehyde which is used in perfumery industry
C
O
H
+ CH3 C
O
H
H H
C C C
O
H
10% NaOH
Cinnamaldehyde
Bezaldehyde
2. Synthesis of Dibenzalacetone which is used as sun protecting agent in sun screen lotion
C
O
H
+ C H 3
C
O
C H 3
N a O H , Aq. E t O H
H
C C H
C
O
C
H
H
C
Dibenzal acetone
B enzaldehyde
2
R.C.P.KASEGAON
63. Application
3. Synthesis of Chacone
4. This reaction also used to synthesis of natural products such as ionone, Flavonone,
piperine etc
C
O
CH3
+ H C
O
C
H
C CH
10% NaOH
Chalcones
Acetophenone
O
Benzaldehyde
ethanol
R.C.P.KASEGAON