2. 2
Organic reactions involve reagents and substrates.
Chemical reagents bring about various types of changes in organic molecules to
yield products of immense value
Reagents have been found that can degrade complex molecules to simple
known molecules which enabled us to elucidate the structures of complex
compounds
A suitable choice of reagent and reaction conditions are essential for the success
of a reaction for the desired product
3. A few of the most important and widely used reagents along with a
few novel catalysts for the synthesis of a large varieties of natural
products, commercially useful chemicals of medicinal and industrial
importance have been included
Their preparations, mode of applications and mechanistic aspects
along with their uses are included
3
4. We discuss the following reagents:-
1) Aluminium isopropoxide
2) N-bromosuccinamide
3) Diazomethane
4) Dicyclohexylcarbodiimide
5) Wilkinson reagent
6) Wittig reagent
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5. It is a good reducing agent
It reduces by transfer of hydride ions
PREPARATION:
Prepared by refluxing anhydrous isopropyl alcohol with aluminium amalgam in the
presence of small amount of carbon tetrachloride as catalyst
After evolution of hydrogen ceases, the mixture is distilled under reduced pressure
and aluminium isopropoxide distills over at 140°C-150°C as a colourless liquid
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6. Some of the applications are given below:-
1) Meerwein-ponndrof reduction:
Crotonaldehyde crotyl alcohol
2-Cyclohexene-1-one 2-Cyclohexene-1-ol
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7. 2) Reduction of diaryl ketones to hydrocarbons:
Anthraquinone Anthracene
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With excess temperature and at higher temperature complete reduction has
been achieved.
8. 3) Oppenauer oxidation:
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Although aluminium-tertiary butoxide is the genrally used catalyst for this
reaction, aluminium isopropoxide has also been used for the oxidation. An
excess of acetone or better hydrogen acceptors like quinones or aryl ketones
are used along with the reagent
10. The reagent is prepared by gradually adding bromine to an ice-
cold solution of succinamide in alkali
NBS precipitates out immediately
Succinamide NBS
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11. 1) AS A BROMINATINGAGENT:
a) PREPARATION OF BROMOESTERS:-
ethyl-γ-bromocrotonate
b) CONVERSION OF MONOENES TO DIENES TO TRIENES:-
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12. 2) AS OXIDISINGAGENT:
3) DEGRADATION OFAMINOACID:
•α-amino acid, peptides and protiens are decarboxylated with NBS in
aqueous medium.
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• NBS oxidizes primary alcohols and primary amines to aldehydes and
secondary alcohols to ketones.
14. 2. Distillation of N-nitroso-N-methyl-p-toluenesulphonamide with base:
14
• Several N-nitroso-N-methyl compounds have been used to prepare diazomethane
1. Alkaline hydrolysis of bis-(N-nitroso-N-methyl) terephthalimide:
15. 1. METHYLATION:
It is used as methylating agent for acidic compounds, alcohols, carbonyl
compounds, amines
Acid
Alcohol
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16. 2. SYNTHESIS OF HETEROCYCLIC COMPOUNDS:
Ethene pyrazole
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• Diazomethane condenses with ethylenic and acetylenic bonds to
give heterocyclic compounds
17. 3. FORMATION OF CARBENE:
• Carbene reacts with hydrocarbons by insertion into carbon-hydrogen bond.
• The reaction is nonselective hence useless for synthesis
17• Photolysis of diazomethane yields carbene which is extremely reactive species
with short life period
18. • Carbene also adds to aliphatic and aromatic double bonds
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20. 1. By the oxidation of N,N‘-dicyclohexylthiourea with mercuric
oxide
2. By the dehydration of dicyclohexylurea with p-toluenesulphonyl chloride in hot
pyridine:-
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21. 1. ESTER:
Esterification of acids with primary or secondary alcohols is promoted by the
reagent
2. ACIDANHYDRIDE:
The reagent gives excellent yield of acid anhydride from carboxylicacids
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22. 3. DIACYL PEROXIDE:
• Diacyl peroxide can be prepared by the treatment of carboxylic acids with
hydrogen peroxide under mild conditions in the presence of this reagent
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24. • It is commonly used for homogenous hydrogenation
• The catalyst is a complex of the transition metal rhodium
• The name of the complex is tris(triphenylphosphine)chlororhodium and its
molecular formula is RhCl(PPh3)3
• The three triphenylposphine (PPh3) ligands are bound to rhodium through the
unshared pair of electrons on phosphorous
• The ligand does not participate in the reaction but their presence is absolutely
essential and influence the course of reaction
• The function of the metal is to form bonds with the substrate and the reagent
and thus bringing them near each other for reaction to follow
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25. 25
• Geometric isomers on hydrogenation with the catalyst having optically
inactive ligands give either meso or a mixture of enantiomers
• However with the use of this catalyst with proper choice of optically active
ligands, one or the other enantiomer may be preferentially formed
• This method has been employed to prepare L-amino acids which are required
for the synthesis protiens
• L-Dopa, an amino acid for the treatment of Parkinson’s disease, is being
prepared on an industrial scale by this method
28. (II)
• Alkylidenetriphenylphosphoranes are also called as ylids due to presence of
opposite formal charges on adjacent atoms as in one of the resonance structure
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• By treating trialkyl or triarylphosphine usually the latter with an alkyl halide in
ether solution
•The resulting phosphonium salt(I) is treated with a strong base (such as C6H5, BuLi,
NaNH2, C2H5ONa, etc) which removes a halacid to give the reagent, methylene
triphenylphosphorane (II)
29. 1) FORMATION OF EXOCYCLIC METHYLENE GROUP:-
2) PREPARATION OF β, γ UNSATURATED ACIDS:-
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