ALDEHYDES, KETONES AND CARBOXYLIC ACIDS
KEY POINTS
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In
aldehydes, the carbonyl group is bonded to a carbon and hydrogen while in the
ketones, it is bonded to two carbon atoms. The carbonyl compounds in which carbonyl
group is bonded to oxygen are known as carboxylic acids, and their
derivatives (e.g. esters, anhydrides) while in compounds where carbon is
attached to nitrogen and to halogens are called amides and acyl halides
respectively. |
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Aldehydes,
Ketones and Carboxylic acids are important classes of organic compounds
containing carbonyl groups. They are highly
polar molecules. They boil at
higher temperatures than the corresponding hydrocarbons and weakly polar
compounds such as ethers. Lower members
are soluble in water because they can form H-bond with water. Higher members
are insoluble in water due to large size of their hydrophobic group. 
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The carbonyl carbon atom is sp2
-hybridised and forms three sigma (σ) bonds. The π Electron
cloud of >C=O is unsymmetrical. On the other hand, due to same
electronegativity of the two carbon atoms, the π-electron of the >C=C<
bond is symmetrical. The
structure of the carbonyl group in aldehydes and Ketones is, not entirely adequately represented by >C=O, nor by the alternative>C+─ O-. The real structure or resonance hybrid lies somewhere between the following structure: its picture coming
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The IUPAC names of open chain aliphatic aldehydes
and ketones are derived from the names of the corresponding alkanes by
replacing the ending –e with –al and –one respectively |
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General
Methods of Preparation: (i) Controlled oxidation of 1º alcohols : RCH2OH PCC/
CrO3--> RCHO RCH2OH Cu/573 K--> RCHO + H2 |
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Preparation of Aldehydes and Ketones (i) By oxidation of alcohols Aldehydes and ketones
are generally prepared by oxidation of primary and secondary alcohols, respectively. RCH2
OH → RCHO By
hydration of alkynes: Ethyne on hydration with HgSO4/dil.H2SO4 at 333 K forms acetaldehyde. 
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By
Rosenmund reduction: Hydrogenation
of acyl chloride over palladium on barium sulphate gives aldehyde RCOCl + H2 Pd/BaSO4---> RCHO
+ HCl
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Stephen
Reaction: Reduction of nitriles in presence of stannous chloride in presence
of HCl gives imine which on hydrolysis gives corresponding aldehyde.  |
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Nitriles
are selectively reduced by DIBAL-H (Diisobutylaluminium hydride) to aldehydes.  |
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From
Hydrocarbons: (i)By
oxidation of methyl benzene: Etard
Reaction: Chromyl chloride (CrO2Cl2) oxidizes methyl
group to a chromium complex, which on hydrolysis gives corresponding benzaldehyde. |
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Benzene
or its derivatives on treatment with carbon monoxide and HCl in presence of
anhydrous aluminium chloride or cuprous chloride (CuCl) gives benzaldehyde or substituted
benzaldehydes.  |
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Oxidation
of secondary alcohols in presence of oxidizing agent like K2Cr2O7/H2SO4, KMnO4,
CrO3 gives ketones. R2CH(OH)
→ RCOR |
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Acyl
chloride on treatment with dialkyl cadmium (prepared by reaction of cadmium chloride
with Grignard reagent) gives ketone.  |
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From
nitriles: Nitriles
on treatment with Grignard reagent followed by hydrolysis give ketones.  |
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By
Friedel Crafts acylation reaction: Benzene
or substituted benzene on treatment with acid chloride in presence of anhydrous
aluminium chloride forms ketone.  |
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The boiling points of aldehydes and ketones are
higher than hydrocarbons and ethers of comparable molecular masses. It is due
to weak molecular association in aldehydes and ketones arising out of the
dipole-dipole interactions. Also, their boiling points are lower than those
of alcohols of similar molecular masses due to absence of intermolecular
hydrogen bonding. The lower members of aldehydes and ketones such
as methanal, ethanal and propanone are miscible with water in all
proportions, because they form hydrogen bond with water. |
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Since aldehydes and ketones both possess the
carbonyl functional group, they undergo similar chemical reactions Aldehydes
are generally more reactive than ketones in nucleophilic addition reactions
due to steric and electronic reasons. Sterically, the presence of two
relatively large substituents in ketones hinders the approach of nucleophile
to carbonyl carbon than in aldehydes having only one such substituent.
Electronically, aldehydes are more reactive than ketones because two alkyl
groups reduce the electrophilicity of the carbonyl carbon more effectively
than in former.   Order of reactivity of aldehydes and ketones towards
nucleophilic addition is : (ii) HCHO > CH3CHO
> CH3CH2CHO. (iii) HCHO > RCHO > R CO R. (iv) ArCHO > Ar COR > Ar CO Ar.
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Nucleophilic
addition reactions of aldehydes and ketones: (a)Addition
of hydrogen cyanide (HCN) to form cyanohydrins : (NaCN+HCl) CH3CHO+
HCN → CH3CH(OH)(CN) |
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(b)Addition
of sodium hydrogensulphite (NaHSO3) to form bisulphate addition Compound |
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(c)Addition
of Grignard reagent (RMgX) to form alcohol
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(d)Addition
of alcohol: (i)
Aldehydes on addition of monohydric alcohol in presence of dry HCl forms
hemiacetal and acetal.  
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(e)Addition
of ammonia and its derivatives:  |
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Reduction
of aldehydes and ketones: (a)
Reduction to alcohols: Aldehydes
and ketones on catalytic hydrogenation in presence of Ni, Pt or Pd by using lithium
aluminium hydride (LiAlH4) or sodium borohydride (NaBH4
) forms primary andsecondary alcohols respectively. |
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Reduction
to hydrocarbons: (i)
Clemmensen reduction: Carbonyl group of aldehydes and ketones is reduced to
CH2 group on treatment with zinc amalgam and concentrated
hydrochloric acid.  |
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Oxidation
of aldehydes and ketones: (i)
Aldehydes are oxidized to acids in presence of mild oxidising agents HNO3,
K2Cr2O7, KMnO4.
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Ketones
are oxidized under drastic conditions i.e. with powerful oxidising agents
like HNO3,
K2Cr2O7, KMnO4. at higher temperature.:
ketones gives mixture of carboxylic acids  |
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Test
to distinguish aldehydes and ketones: 1)
Tollen’s test: When an aldehyde is heated with Tollen’s reagent it forms
silver mirror. . Tollen’s
reagent is ammoniacal solution of AgNO3 Ketones do not form silver mirror and hence do not give this test.  |
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Fehling’s
test: When an aldehyde is heated with Fehling’s reagent it forms reddish brown
precipitates of cuprous oxide. Fehling’s reagent: Fehling solution A (aqueous solution
of CuSO4) + Fehling solution B (alkaline solution of sodium
potassium tartarate)  Ketones
do not give this test. |
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ALDOL
CONDENSATION : Aldehydes and ketones having
at least one α-hydrogen condense in the presence of dilute alkali to form β-hydroxy aldehydes or β
–hydroxyketones (aldol)(ketol).  Cross
aldol condensation: Aldol condensation between two different aldehydes and ketones
is called aldol condensation. If both of them contain α -hydrogen atoms, it
gives a mixture of four products.  |
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(iii)Haloform
reaction: Aldehydes and ketones having at least one methyl group linked to
the carbonyl carbon atom i.e. methyl ketones are oxidised by sodium hypohalite
to sodium
salts of corresponding carboxylic acids having one carbon atom less than that
of carbonyl compound. The methyl group is converted to haloform.  |
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Carboxylic
Acids: Carboxylic acids are the compounds containing the carboxylfunctional
group (-COOH). |
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Preparation
of carboxylic acid: (i)
From alcohols: Primary alcohols are readily oxidised to carboxylic acids with common
oxidising agents such as potassium permanganate (KMnO4) in
neutral, acidic oralkaline media or by potassium dichromate (K2Cr2O7)
and chromium trioxide (CrO3) in acidic media.  |
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(iii)From
alkyl benzenes: Aromatic carboxylic acids can be prepared by vigorous oxidation
of alkyl benzenes with chromic acid or acidic or alkaline potassium permanganate.  |
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(v)From
Nitriles: Nitriles on hydrolysis in presence of dilute acids or bases forms
amide which on further hydrolysis gives carboxylic acid.  |
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From
Grignard reagent: Grignard reagents react with carbon dioxide (dry ice) to form
salts of carboxylic acids which on hydrolysis forms carboxylic acids.  |
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From
acyl halides and anhydrides: Acid chlorides when hydrolysed with water give carboxylic
acids .On basic hydrolysis carboxylate ions are formed which on further acidification
forms corresponding carboxylic acids. Anhydrides on hydrolysis forms corresponding
acid(s) From
esters: Acidic hydrolysis of esters gives directly carboxylic acids while
basic hydrolysis
gives carboxylates, which on acidification give corresponding carboxylic acids.  |
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Physical
properties of carboxylic acids: (i)Solubility:
As the size of alky group increases solubility of carboxylic acid decreases
because non-polar part of the acid increases (ii)Boiling
points: Carboxylic acids are higher boiling liquids than aldehydes, ketones and
even alcohols of comparable molecular masses. This is due to extensive
association of carboxylic acid molecules through intermolecular hydrogen
bonding. |
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Acidity
of carboxylic acids: Carboxylic
acids are more acidic than phenols. The strength of acid depends on extent of
ionization which in turn depends on stability of anion formed. (i)Effect
of electron donating substituents on the acidity of carboxylic acids:
Electron donating
substituent decreases stability of carboxylate ion by intensifying the
negative charge
and hence decreases acidity of carboxylic acids. (ii)Effect
of electron withdrawing substituent on the acidity of carboxylic acids:
Electronwithdrawing group increases the stability of carboxylate ion by
delocalizing negativecharge and hence, increases acidity of carboxylic acid.
The effect of the following groups in
increasing acidity order is Ph < I < Br < Cl < F < CN < NO2
< CF3 |
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Reaction
of carboxylic acids: Reaction
with Na metal NaOH, NaHCO3  |
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Esterification:
Carboxylic acids are esterified with alcohols in the presence of a mineral
acid such as concentrated H2SO4 or HCl gas as a catalyst.  (iii) Carboxylic acids react with PCl5,
PCl3 and SOCl2 to form acyl chlorides.  |
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Reaction
with ammonia (NH3): Carboxylic acids react with ammonia to give ammonium
salt which on further heating at high temperature gives amides.  |
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(ii)Decarboxylation
: Sodium or potassium salts of carboxylic acids on heating with sodalime
(NaOH + CaO in ratio of 3:1) gives hydrocarbons which contain one carbon less
thanthe parent acid.  |
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Hell-Volhard-Zelinsky
reaction: Carboxylic acids having an α -hydrogen are halogenated
at the α -position on treatment with chlorine or bromine in the presence of small
amount of red phosphorus to give α -halocarboxylic acids) 
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(ii)Ring substitution in aromatic acids: Aromatic carboxylic acids undergo electrophilicsubstitution reactions. Carboxyl group in benzoic acid is electron withdrawing group and is meta- directing. 
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