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CONTENTS

FOREWORD iii
PREFACE V

Unit 10 Haloalkanes and Haloarenes 281
10.1 Classification 282
10.2 Nomenclature 283
10.3 Nature of C3X Bond 285

E
10.4 Methods of Preparation 286
10.5 Physical Properties 289
10.6 Chemical Reactions 291
10.7 Polyhalogen Compounds 308

Unit 11 Alcohols, Phenols and Ethers 315
11.1 Classification 316
11.2 Nomenclature 317
11.3 Structures of Functional Groups 320
11.4 Alcohols and Phenols 321
11.5 Some Commercially Important Alcohols 336

Unit 12
11.6 Ethers
15
Aldehydes, Ketones and Carboxylic Acids
05 337

349
12.1 Nomenclature and Structure of Carbonyl Group 350
12.2 Preparation of Aldehydes and Ketones 353
12.3 Physical Properties 357
12.4
12.5
12.6
Chemical Reactions
Uses of Aldehydes and Ketones 15
Nomenclature and Structure of Carboxyl Group
358
365
366
12.7 Methods of Preparation of Carboxylic Acids 367
12.8 Physical Properties 371
12.9 Chemical Reactions 371
12.10 Uses of Carboxylic Acids 376
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Unit 13 Amines 381
13.1 Structure of Amines 381
13.2 Classification 382
13.3
13.4
Nomenclature
Preparation of Amines 10 382
384
13.5 Physical Properties 387
13.6 Chemical Reactions 388
13.7 Method of Preparation of Diazonium Salts 396
13.8 Physical Properties 397
13.9 Chemical Reactions 397
13.10 Importance of Diazonium Salts in Synthesis of 398
Aromatic Compounds

Unit 14 Biomolecules 403
14.1 Carbohydrates 403
14.2 Proteins 412
14.3 Enzymes 417
14.4
14.5
Vitamins
Nucleic Acids
10 417
419

Unit 15 Polymers 425
15.1 Classification of Polymers 426
15.2
15.3
15.4
Types of Polymerisation
Molecular Mass of Polymers
Biodegradable Polymers
05 428
435
435
15.5 Polymers of Commercial Importance 436

Unit 16 Chemistry in Everyday Life 439
16.1 Drugs and their Classification 439
16.2 Drug-Target Interaction 440
16.3 Therapeutic Action of Different Classes of Drugs 443
16.4 Chemicals in Food 449
16.5 Cleansing Agents 450

Answers to Some Questions in Exercises 456

Index 461

xii
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INDEX
Terms Page No. Terms Page No.

Achiral 297 Baeyers' reagent 362
Acidity of alcohols 327 Bakelite 428, 432
Acidity of phenols 328 Barbiturates 445
Active site 440 Benzylic alcohols 317
Acylation 392 Benzylic halides 282, 295
Addition polymers 427 Biodegradable polymers 435
Adduct 323 Biomolecules 403
Alcohols 315, 317, 321 Branched chain polymers 426
Aldehydes 349, 350, 352 Broad spectrum antibiotics 447
Aldol condensation 363 Buna - N 428, 435
Aldol reaction 363 Buna - S 427
Aldopentose 412 Cannizzaro reaction 364
Alkanamines 382, 390 Carbocation 295, 300
Alkenes 288 Carbohydrates 403
Alkyl halides 281, 282 Carboxylic acids 349, 366
Alkylation 392 Carbylamine reaction 393
Alkylbenzenes 368 Catalytic action of enzymes 440
Alkynes 354 Cationic detergents 452
Allosteric site 441 Cellulose 411
Allylic alcohols 316 Chain initiating step 429
Allylic halides 282, 295 Chain propagating step 429
Ambident nucleophiles 292 Chain terminating step 429
Amines 381 Chemical messengers 442
Amino acids 412 Chemotherapy 439
Ammonolysis 384 Chirality 296, 297
Amylopectin 410 Cleansing agents 450
Amylose 410 Clemmensen reduction 360
Analgesics 444 Coagulation 417
Anhydrides 369 Competitive inhibitors 441
Animal starch 411 Condensation polymers 427
Anionic detergents 452 Copolymerisation 433
Anomers 408 Copolymers 427
Antacids 443 Cross aldol condensation 364
Antibiotics 445 Cross linked polymers 426
Antidepressant drugs 444 Cumene 324
Antifertility drugs 448 Cyclic structure 407
Antihistamines 443 DDT 309
Antimicrobial drugs 446 Dehydrogenation 331
Antipyretic 445 Denaturation 336
Antiseptics 446, 448 Denaturation of protein 416
Aromatic ring 317 Deoxyribonucleic acid 419
Artificial sweetening agents 449 Deoxyribose 412
Aryl halides 283 Detergents 450
Arylamines 383, 391 Dextrorotatory 296
Aspirin 445 Diazonium salt 287, 288
Asymmetric carbon 297 Diazonium salts 396
Azo dyes 400 Diazotisation 396
Bactericidal 447 Disaccharides 404, 409
Bacteriostatic 447 Disinfectants 446, 448
461 Index

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Terms Page No. Terms Page No.

Drug - enzyme interaction 441 Hinsberg's reagent 393
Drug - target interaction 440 Histamines 443
Drugs 439 Hoffmann bromamide reaction 386
Elastomers 427 Hydroboration 322
Electron donating group 372 Hyperacidity 443
Electron withdrawing group 372 Intermolecular bonding 333
Electrophilic aromatic substitution 333, 341 Intramolecular bonding 333
Electrophilic substitution 287, 305 Inversion of configuration 293
Electrostatic forces 415 Invert sugar 409
Elimination reaction 291 Ketones 349, 352, 353
Emulsifiers 449 Kolbe electrolysis 375
Enantiomers 296, 298 Kolbe's reaction 334
Environmental pollution 454 Lactose 410
Enzyme inhibitors 441 Laevorotatory 296
Enzymes 417 Laundry soaps 451
Esterification 329 Lewis bases 399
Esters 322 Limited spectrum antibiotics 447
Etard reaction 355 Linear polymers 426
Ethers 315, 317, 319 Low density polythene 429
Fat soluble vitamins 418 Lucas test 330
Fatty acids 366 Maltase 417
Fehling's test 361 Maltose 409
Fibres 428 Markovnikov's rule 321, 322
Fibrous proteins 414 Medicated soaps 451
Finkelstein reaction 289 Medicines 439
Fittig reaction 307 Melamine - formaldehyde polymer 431
Free radical 286 Messenger - RNA 421
Free radical mechanism 429 Molecular asymmetry 296
Freon refrigerant 309 Molecular targets 440
Friedel-Crafts reaction 305, 356 Monosaccharides 404
Fructose 408 Narrow spectrum antibiotics 447
Furanose 408 Natural polymers 426
Gabriel phthalimide synthesis 386 Natural rubber 433
Gatterman - Koch reaction 355 Neoprene 428, 434
Gatterman reaction 397 Network polymers 426
Geminal halides 283, 284 Nitration 395
Globular proteins 415 Nomenclature 283
Gluconic acid 405 Non-biodegradable 454
Glucose 405 Non-ionic detergents 452
Glyceraldehyde 406 Non-narcotic analgesics 445
Glycogen 411 Novolac 431
Glycosidic linkage 409, 410 Nucleic acids 419
Grignard reagent 301 Nucleophilic substitution 291
Haloalkane 281, 291 Nucleosides 420
Haloarene 281, 324 Nucleotides 419
Halogenation 334, 341 Nylon 6 431
Haworth structures 408 Nylon 6, 6 425, 427, 431
Hell - Volhard Zelinsky reaction 375 Oligosaccharides 404
Hemiacetal 359 Optical isomerism 296
Heterocyclic compounds 419 Optically inactive 299
High density polythene 430 Organo-metallic compounds 301

Chemistry 462

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Terms Page No. Terms Page No.

3
Oxidoreductase 417 Sp hybridised 381
Ozonolysis 353 Starch 405
Peptide bond 414 Stephen reaction 354
Peptide linkage 414 Stereo centre 297
PHBV 435 Structure - basicity relationship 390
Phenols 315, 318 Structure of proteins 414
Polarity 358 Substitution nucleophilic bimolecular 293
Polyacrylonitrile 430 Substitution nucleophilic unimolecular 294
Polyamides 431 Sucrose 405, 409
Polyesters 431 Sulphonation 395
Polyhydric compounds 316 Swarts reaction 289
Polymerisation 425 Sweeteners 449
Polymers 425 Synthetic detergents 451
Polysaccharides 404, 410 Synthetic polymers 426
Polythene 427, 429 Synthetic rubber 434
Preservatives 449, 450 Teflon 430
Propellants 308 Terylene 428
Proteins 412 Thermoplastic polymers 428
Protic solvents 295 Thermosetting polymers 428
Pyranose structure 408 Toilet soaps 451
Racemic mixture 298 Tollens' test 361
Racemisation 296 Tranquilizers 444
Receptors 440 Transfer - RNA 421
Reducing sugars 404 Transparent soaps 451
Reimer - Tiemann reaction 335 Trisaccharides 404
Resins 428, 436 van der Waal forces 290
Ribose 412 Vasodilator 443
Ribosomal - RNA 421 Vicinal halides 283, 284
Ring substitution 376 Vinylic alcohol 317
Rochelle salt 361 Vinylic halides 283
Rosenmund reduction 354 Vitamins 417, 418
Rubber 433 Vulcanisation 434
Saccharic acid 406 Water soluble vitamins 418
Salvarsan 446 Williamson synthesis 337
Sandmayer's reaction 287, 397 Wolff - Kishner reduction 361
Saponification 450 Wurtz reaction 302
Scouring soaps 451 Wurtz-Fittig reaction 307
Semi - synthetic polymers 426 Ziegler - Natta catalyst 430
Shaving soaps 451 Zwitter ion 414
Soaps 450

463 Index

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Unit
U it

Objectives
10
Haloalkanes
Haloalkane
Halo
loalkanes
loaaallka ness and
kane and
After studying this Unit, you will be
able to
name haloalkanes and haloarenes
Haloar
a lloar
oa renes
Haloarenes
Haloaren
H es
according to the IUPAC system of
nomenclature from their given
structures; Halogenated compounds persist in the environment due to their
describe the reactions involved in resistance to breakdown by soil bacteria.
the preparation of haloalkanes and
haloarenes and understand
various reactions that they The replacement of hydrogen atom(s) in a
undergo; hydrocarbon, aliphatic or aromatic, by halogen
correlate the structures of atom(s) results in the formation of alkyl halide
haloalkanes and haloarenes with (haloalkane) and aryl halide (haloarene), respectively.
various types of reactions; Haloalkanes contain halogen atom(s) attached to the
use stereochemistry as a tool for sp3 hybridised carbon atom of an alkyl group whereas
understanding the reaction
haloarenes contain halogen atom(s) attached to sp2
mechanism;
hybridised carbon atom(s) of an aryl group. Many
appreciate the applications of
organo-metallic compounds;
halogen containing organic compounds occur in
nature and some of these are clinically useful. These
highlight the environmental effects
of polyhalogen compounds. classes of compounds find wide applications in
industry as well as in day-to-day life. They are used
as solvents for relatively non-polar compounds and
as starting materials for the synthesis of wide range
antibiotic of organic compounds. Chlorine containing antibiotic,

chloramphenicol t d
chloramphenicol, produced by soil microorganisms
is very effective for the treatment of typhoid fever.
Our body produces iodine containing hormone,
Typhoid fever thyroxine, the deficiency of which causes a disease
called goiter. Synthetic halogen compounds, viz.
thyroxine L I chloroquine is used for the treatment of malaria;
halothane is used as an anaesthetic during surgery.
Certain fully fluorinated compounds are being
deficiencycausegoiter considered as potential blood substitutes in surgery.
In this Unit, you will study the important methods
synthetichalogencompound of preparation, physical and chemical properties and
uses of organohalogen compounds.
chloroquine
for malaria treatment
v
Halothane anaesthetic
EIC e
I surgery
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10.11 Classification
l at Haloalkanes and haloarenes may be classified as follows:

10.1.1 On the These may be classified as mono, di, or polyhalogen (tri-,tetra-, etc.)
Basis of compounds depending on whether they contain one, two or more halogen
Number of atoms in their structures. For example,
Halogen
Atoms

Monohalocompounds may further be classified according to the
hybridisation of the carbon atom to which the halogen is bonded, as
discussed below.
10.1.2 Compounds This class includes
Containing (a) Alkyl halides or haloalkanes (R4X)
sp3 C4X
Bond (X= F, In alkyl halides, the halogen atom is bonded to an alkyl group (R).
Cl, Br, I) They form a homologous series represented by CnH2n+1X. They are
further classified as primary, secondary or tertiary according to the
nature of carbon to which halogen is attached.

(b) Allylic halides
These are the compounds in which the halogen atom is bonded to an
sp3-hybridised carbon atom next to carbon-carbon double bond (C=C)
i.e. to an allylic carbon.

(c) Benzylic halides
These are the compounds in which the halogen atom is bonded to an
sp3-hybridised carbon atom next to an aromatic ring.

Chemistry 282

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10.1.3 Compounds
Containing
sp2 C4X
Bond
This class includes:
(a) Vinylic halides AE
These are the compounds in which the halogen atom is bonded to
an sp2-hybridised carbon atom of a carbon-carbon double bond
(C = C).

(b) Aryl halides
These are the compounds in which the halogen atom is bonded to
the sp2-hybridised carbon atom of an aromatic ring.

10.2 o l tu
Nomenclature Having learnt the classification of halogenated compounds, let us now
learn how these are named. The common names of alkyl halides are
derived by naming the alkyl group followed by the halide. Alkyl halides
are named as halosubstituted hydrocarbons in the IUPAC system of
nomenclature. Haloarenes are the common as well as IUPAC names of
aryl halides. For dihalogen derivatives, the prefixes o-, m-, p- are used in
common system but in IUPAC system, the numerals 1,2; 1,3 and 1,4 are
used.

alkylidenelThe dihaloalkanes having the same type of halogen atoms are named
dihalides
as alkylidene or alkylene dihalides. The dihalo-compounds having same

R
Choi'Ll type of halogen atoms are further classified as geminal halides (halogen
atoms are present on the same carbon atom) and vicinal halides (halogen
alleylene atoms are present on the adjacent carbon atoms). In common name
ch 942 dihalids system, gem-dihalides are named as alkylidene halides and vic-dihalides
R I
te 283 Haloalkanes and Haloarenes

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are named as alkylene dihalides. In IUPAC system, they are named as
dihaloalkanes.

Some common examples of halocompounds are mentioned in Table 10.1.
Table 10.1: Common and IUPAC names of some Halides

Structure Common name IUPAC name

CH3CH2CH(Cl)CH3 sec-Butyl chloride 2-Chlorobutane

(CH3)3CCH2Br neo-Pentyl bromide 1-Bromo-2,2-dimethylpropane

(CH3)3CBr tert-Butyl bromide 2-Bromo-2-methylpropane

CH2 = CHCl Vinyl chloride Chloroethene

CH2 = CHCH2Br Allyl bromide 3-Bromopropene

o-Chlorotoluene 1-Chloro-2-methylbenzene
or
2-Chlorotoluene
Benzyl chloride Chlorophenylmethane

CH2Cl2 Methylene chloride Dichloromethane

CHCl3 Chloroform Trichloromethane

CHBr3 Bromoform Tribromomethane

CCl4 Carbon tetrachloride Tetrachloromethane

CH3CH2CH2F n-Propyl fluoride 1-Fluoropropane

E
Example 0 1 Draw the structures of all the eight structural isomers that have the
p 10.1
molecular formula C5H11Br. Name each isomer according to IUPAC system
and classify them as primary, secondary or tertiary bromide.
S l uti
Solution CH3CH2CH2CH2CH2Br 1-Bromopentane (1 )
o

CH3CH2CH2CH(Br)CH3 2-Bromopentane(2o)
CH3CH2CH(Br)CH2CH3 3-Bromopentane (2o)
(CH3)2CHCH2CH2Br 1-Bromo-3-methylbutane (1o)

Chemistry 284

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o
(CH3)2CHCHBrCH3 2-Bromo-3-methylbutane(2 )
o
(CH3)2CBrCH2CH3 2-Bromo-2-methylbutane (3 )
o
CH3CH2CH(CH3)CH2Br 1-Bromo-2-methylbutane(1 )
o
(CH3)3CCH2Br 1-Bromo-2,2-dimethylpropane (1 )

Write IUPAC names of the following: e 10.2
Example
x 1.

(i) 4-Bromopent-2-ene (ii) 3-Bromo-2-methylbut-1-ene o
Solution
n
(iii) 4-Bromo-3-methylpent-2-ene (iv) 1-Bromo-2-methylbut-2-ene
(v) 1-Bromobut-2-ene (vi) 3-Bromo-2-methylpropene

t t Question
Intext Q si
10.1 Write structures of the following compounds:
(i) 2-Chloro-3-methylpentane
(ii) 1-Chloro-4-ethylcyclohexane
(iii) 4-tert. Butyl-3-iodoheptane
(iv) 1,4-Dibromobut-2-ene
(v) 1-Bromo-4-sec. butyl-2-methylbenzene.

1 0. 3 Nature
r of Since halogen atoms are more electronegative than carbon, the carbon-
halogen bond of alkyl halide is polarised; the carbon atom bears a
C-X BoBond partial positive charge whereas the halogen atom bears a partial negative
charge.

Since the size of halogen atom increases as we go down the group
in the periodic table, fluorine atom is the smallest and iodine atom, the
largest. Consequently the carbon-halogen bond length also increases
from C4F to C4I. Some typical bond lengths, bond enthalpies and
dipole moments are given in Table 10.2.

285 Haloalkanes and Haloarenes

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Irs
Table 10.2: Carbon-Halogen (C4X) Bond Lengths, Bond
Enthalpies and Dipole Moments

Bond Bond length/pm C-X Bond enthalpies/ kJmol-1 Dipole moment/Debye
CH33F 139 452 1.847 I
CH33 Cl 178 351 1.860
I Max
CH33Br 193 293 1.830
II
CH33I 214 234 1.636
II Min
4 Methods
10.4 e h d of 10.4.1 From Alcohols
Preparation
r aarr i Alkyl halides are best prepared from alcohols, which are easily accessible.
The hydroxyl group of an alcohol is replaced by halogen on reaction
with concentrated halogen acids, phosphorus halides or thionyl chloride.
Thionyl chloride is preferred because the other two products are
escapable gases. Hence the reaction gives pure alkyl halides. Phosphorus
tribromide and triiodide are usually generated in situ (produced in the
reaction mixture) by the reaction of red phosphorus with bromine and
OH iodine respectively. The preparation of alkyl chloride is carried out either
w by passing dry hydrogen chloride gas through a solution of alcohol or
SN ke by heating a solution of alcohol in concentrated aqueous acid.

Evita ce
Racemic
mix

GT GT
0Ht my
2nd The reactions of primary and secondary alcohols with HX require
f the presence of a catalyst, ZnCl2. With tertiary alcohols, the reaction is
conducted by simply shaking with concentrated HCl at room
HI
2nd temperature. Constant boiling with HBr (48%) is used for preparing
2 04 1 alkyl bromide. Good yields of R4I may be obtained by heating alcohols
i
27 with sodium or potassium iodide in 95% phosphoric acid. The order
of reactivity of alcohols with a given haloacid is 3 >2 >1. The above
H HI Eon method is not applicable for the preparation of aryl halides because the

Rj simpleshaking
carbon-oxygen bond in phenols has a partial double bond character
and is difficult to break being stronger than a single bond (Unit 11,
Class XI).
no need of2nd
10.4.2 From (a) By free radical halogenation
Hydrocarbons Free radical chlorination or bromination of alkanes gives a complex
Chemistry 286 constant R Br
ROH HBy
Boiling
48
Phosphoric
R Oh NAI 951 D R goodyield
or acir
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mixture of isomeric mono- and polyhaloalkanes, which is difficult
to separate as pure compounds. Consequently, the yield of any one
compound is low (Unit 13, Class XI).

Identify all the possible monochloro structural isomers expected to be x m e 10.3
Example 03
formed on free radical monochlorination of (CH3)2CHCH2CH3.
In the given molecule, there are four different types of hydrogen atoms. o n
Solution
Replacement of these hydrogen atoms will give the following
(CH3)2CHCH2CH2Cl (CH3)2CHCH(Cl)CH3
(CH3)2C(Cl)CH2CH3 CH3CH(CH2Cl)CH2CH3

(b) By electrophilic substitution
Aryl chlorides and bromides can be easily prepared by electrophilic
substitution of arenes with chlorine and bromine respectively in the
presence of Lewis acid catalysts like iron or iron(III) chloride.

EEpisLated due
to difference
The ortho and para isomers can be easily separated due to large in M P
difference in their melting points. Reactions with iodine are reversible
in nature and require the presence of an oxidising agent (HNO3,
HIO4) to oxidise the HI formed during iodination. Fluoro compounds
are not prepared by this method due to high reactivity of fluorine.
(c) Sandmeyer9s reaction
When a primary aromatic amine, dissolved or suspended in cold
aqueous mineral acid, is treated with sodium nitrite, a diazonium
salt is formed (Unit 13, Class XII). Mixing the solution of freshly
prepared diazonium salt with cuprous chloride or cuprous bromide
results in the replacement of the diazonium group by 3Cl or 3Br.

cold aq
mineral acid

287 Haloalkanes and Haloarenes

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Replacement of the diazonium group by iodine does not require the
presence of cuprous halide and is done simply by shaking the diazonium
salt with potassium iodide.

(d) From alkenes
(i) Addition of hydrogen halides: An alkene is converted to
corresponding alkyl halide by reaction with hydrogen chloride,
hydrogen bromide or hydrogen iodide.

Propene yields two products, however only one predominates as
per Markovnikov9s rule. (Unit 13, Class XI)

(ii) Addition of halogens: In the laboratory, addition of bromine in
CCl4 to an alkene resulting in discharge of reddish brown colour
of bromine constitutes an important method for the detection of
double bond in a molecule. The addition results in the synthesis
of vic-dibromides, which are colourless (Unit 13, Class XI).

mp e 10.4
Example 04 Write the products of the following reactions:

Solution
o o

Chemistry 288

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10.4.3 Halogen Alkyl iodides are often prepared by the reaction of alkyl chlorides/
Exchange bromides with NaI in dry acetone. This reaction is known as Finkelstein
reaction.

NaCl or NaBr thus formed is precipitated in dry acetone. It facilitates
the forward reaction according to Le Chatelier9s Principle.
The synthesis of alkyl fluorides is best accomplished by heating an
alkyl chloride/bromide in the presence of a metallic fluoride such as
AgF, Hg2F2, CoF2 or SbF3. The reaction is termed as Swarts reaction.

I
Intext ttii s
Questions
10.2 Why is sulphuric acid not used during the reaction of alcohols with KI?
10.3 Write structures of different dihalogen derivatives of propane.
10.4 Among the isomeric alkanes of molecular formula C5H12, identify the one that
on photochemical chlorination yields
(i) A single monochloride.
(ii) Three isomeric monochlorides.
(iii) Four isomeric monochlorides.
10.5 Draw the structures of major monohalo products in each of the following
reactions:

10.55 Physical
h s ic Alkyl halides are colourless when pure. However, bromides and iodides
develop colour when exposed to light. Many volatile halogen compounds
r r ie
Properties have sweet smell.

289 Haloalkanes and Haloarenes

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Eats
a Melting and boiling points
Methyl chloride, methyl bromide, ethyl chloride and some
chlorofluoromethanes are gases at room temperature. Higher members
are liquids or solids. As we have already learnt, molecules of organic
T halogen compounds are generally polar. Due to greater polarity as well
as higher molecular mass as compared to the parent hydrocarbon, the
F intermolecular forces of attraction (dipole-dipole and van der Waals)
Cydfluoro are stronger in the halogen derivatives. That is why the boiling points
of chlorides, bromides and iodides are considerably higher than those
chloro
methane of the hydrocarbons of comparable molecular mass.
The attractions get stronger as the molecules get bigger in size and
have more electrons. The pattern of variation of boiling points of different
halides is depicted in Fig. 10.1. For the same alkyl group, the boiling
points of alkyl halides decrease in the order: RI> RBr> RCl> RF. This
is because with the increase in size and mass of halogen atom, the
magnitude of van der Waal forces increases.

Fig. 10.1: Comparison of boiling points of some alkyl halides

The boiling points of isomeric haloalkanes decrease with increase in
branching (Unit 12, Class XI). For example, 2-bromo-2-methylpropane
has the lowest boiling point among the three isomers.

l z z

n i so neo
Boiling points of isomeric dihalobenzenes are very nearly the same.
However, the para-isomers are high melting as compared to their ortho-
and meta-isomers. It is due to symmetry of para-isomers that fits in
crystal lattice better as compared to ortho- and meta-isomers.

Chemistry 290

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diff sepereter
MP can be

y
O 0
Density
Bromo, iodo and polychloro derivatives of hydrocarbons are heavier than
water. The density increases with increase in number of carbon atoms,
halogen atoms and atomic mass of the halogen atoms (Table 10.3).

Table 10.3: Density of some Haloalkanes
in Compound Density (g/mL) Compound Density (g/mL)

n3C3H7Cl 0.89 CH2Cl2 1.336
wire n3C3H7Br 1.335 CHCl3 1.489

in n-C3H7I 1.747 CCl4 1.595

Solubility
The haloalkanes are only very slightly soluble in water. In order for a
haloalkane to dissolve in water, energy is required to overcome the
attractions between the haloalkane molecules and break the hydrogen
bonds between water molecules. Less energy is released when new
attractions are set up between the haloalkane and the water molecules
as these are not as strong as the original hydrogen bonds in water. As a
result, the solubility of haloalkanes in water is low. However, haloalkanes
tend to dissolve in organic solvents because the new intermolecular
attractions between haloalkanes and solvent molecules have much the
same strength as the ones being broken in the separate haloalkane and
solvent molecules.

IIntext
Inn x Question
e t on
on
10.6 Arrange each set of compounds in order of increasing boiling points.
(i) Bromomethane, Bromoform, Chloromethane, Dibromomethane.
(ii) 1-Chloropropane, Isopropyl chloride, 1-Chlorobutane.

em l
10.6 Chemical 10.6.1 Reactions of Haloalkanes
a
Reactions The reactions of haloalkanes may be divided into the following categories:
(i) Nucleophilic substitution
(ii) Elimination reactions
(iii) Reaction with metals.
(i) Nucleophilic substitution reactions
In this type of reaction, a nucleophile reacts with haloalkane (the
substrate) having a partial positive charge on the carbon atom bonded
291 Haloalkanes and Haloarenes

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to halogen. A substitution reaction takes place and halogen atom,
called leaving group departs as halide ion. Since the substitution
reaction is initiated by a nucleophile, it is called nucleophilic
substitution reaction.

It is one of the most useful classes of organic reactions of alkyl
halides in which halogen is bonded to sp3 hybridised carbon. The
products formed by the reaction of haloalkanes with some common
nucleophiles are given in Table 10.4.

Table 10.4: Nucleophilic Substitution of Alkyl Halides (R3X)

Reagent Nucleophile Substitution Class of main
(Nu3) product R3Nu product
NaOH (KOH) HO3 ROH Alcohol
H2O H2O ROH Alcohol

NaOR R O3 ROR Ether
NaI I 3
R4I Alkyl iodide
NH3 NH3 RNH2 Primary amine
R NH2 R NH2 RNHR Sec. amine
R R NH RR H RNR R Tert. amine
KCN RCN Nitrile
(cyanide)
AgCN Ag-CN: RNC Isonitrile
(isocyanide)
KNO2 O=N4O R4O4N=O Alkyl nitrite
AgNO2 Ag4Ö4N=O R4NO2 Nitroalkane
R COOAg R COO3 R COOR Ester
LiAlH4 H RH Hydrocarbon
R 3 M+ R3 RR Alkane

Groups like cyanides and nitrites possess two nucleophilic centres
and are called ambident nucleophiles. Actually cyanide group is a
hybrid of two contributing structures and therefore can act as a
nucleophile in two different ways [ C N :C=N ], i.e., linking through
carbon atom resulting in alkyl cyanides and through nitrogen atom
leading to isocyanides. Similarly nitrite ion also represents an ambident
nucleophile with two different points of linkage [3O4 =O]. The linkage
through oxygen results in alkyl nitrites while through nitrogen atom,
it leads to nitroalkanes.
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Haloalkanes react with KCN to form alkyl cyanides as main product mp e 110.5
Example
while AgCN forms isocyanides as the chief product. Explain.
KCN is predominantly ionic and provides cyanide ions in solution. Solution
S llutio
uti o
Although both carbon and nitrogen atoms are in a position to donate
electron pairs, the attack takes place mainly through carbon atom and
not through nitrogen atom since C4C bond is more stable than C4N
bond. However, AgCN is mainly covalent in nature and nitrogen is free
to donate electron pair forming isocyanide as the main product.

Mechanism: This reaction has been found to proceed by two different
mechanims which are described below:
(a) Substitution nucleophilic bimolecular (SN2)
The reaction between CH3Cl and hydroxide ion to yield methanol and
chloride ion follows a second order kinetics, i.e., the rate depends
upon the concentration of both the reactants.

As you have already learnt in Section 12.3.2 of Class XI, the solid wedge represents the
bond coming out of the paper, dashed line going down the paper and a straight line
representing bond in the plane of the paper.

This can be represented diagrammatically as shown in Fig. 10.2.

Fig. 10.2: Red dot represents the incoming hydroxide ion and green dot represents the
outgoing halide ion

It depicts a bimolecular nucleophilic displacement (SN2) reaction;
the incoming nucleophile interacts with alkyl halide causing the carbon-
halide bond to break while forming a new carbon-OH bond. These two
In the year 1937,
processes take place simultaneously in a single step and no intermediate
Edward Davies Hughes
and Sir Christopher
is formed. As the reaction progresses and the bond between the
Ingold proposed a nucleophile and the carbon atom starts forming, the bond between
mechanism for an SN2 carbon atom and leaving group weakens. As this happens, the
reaction. configuration of carbon atom under attack inverts in much the same
way as an umbrella is turned inside out when caught in a strong wind,
while the leaving group is pushed away. This process is called as
inversion of configuration. In the transition state, the carbon atom is
simultaneously bonded to incoming nucleophile and the outgoing leaving

293 Haloalkanes and Haloarenes

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T S
group and such structures are unstable and cannot be isolated. This
is because the carbon atom in the transition state is simultaneously
bonded to five atoms and therefore is unstable.
Since this reaction requires the approach of the nucleophile to the
carbon bearing the leaving group, the presence of bulky substituents
Hughes worked under
Ingold and earned a
on or near the carbon atom have a dramatic inhibiting effect. Of the
D.Sc. degree from the simple alkyl halides, methyl halides react most rapidly in SN2 reactions
University of London. because there are only three small hydrogen atoms. Tertiary halides are
the least reactive because bulky groups hinder the approaching
nucleophiles. Thus the order of reactivity followed is:
Primary halide > Secondary halide > Tertiary halide.

Fig.10.3: Steric effects in SN2 reaction. The relative rate of SN2 reaction is given in parenthesis

(b) Substitution nucleophilic unimolecular (SN1)
SN1 reactions are generally carried out in polar protic solvents (like
water, alcohol, acetic acid, etc.). The reaction between tert-butyl
bromide and hydroxide ion yields tert-butyl alcohol and follows
the first order kinetics, i.e., the rate of reaction depends upon the
concentration of only one reactant, which is tert- butyl bromide.

tag
It occurs in two steps. In step I, the polarised C4Br bond undergoes
slow cleavage to produce a carbocation and a bromide ion. The
carbocation thus formed is then attacked by nucleophile in step II
to complete the substitution reaction.

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Step I is the slowest and reversible. It involves the C3Br bond breaking for which the
energy is obtained through solvation of halide ion with the proton of protic solvent. Since
the rate of reaction depends upon the slowest step, the rate of reaction depends only on the
concentration of alkyl halide and not on the concentration of hydroxide ion. Further, greater
the stability of carbocation, greater will be its ease of formation from alkyl halide and faster
will be the rate of reaction. In case of alkyl halides, 30 alkyl halides undergo SN1 reaction
0
very fast because of the high stability of 3 carbocations. We can sum up the order of reactivity
of alkyl halides towards S N1 and SN2 reactions as follows:

For the same reasons, allylic and benzylic halides show high reactivity towards the SN1
reaction. The carbocation thus formed gets stabilised through resonance (Unit 12, Class XI) as
shown below.

For a given alkyl group, the reactivity of the halide, R-X, follows the same order in both the
mechanisms R3I> R3Br>R3Cl>>R3F.

In the following pairs of halogen compounds, which would undergo xa
Example 06
10.6
SN2 reaction faster?

It is primary halide and therefore undergoes SN2 S ut o
Solution
reaction faster.

As iodine is a better leaving group because of its
large size, it will be released at a faster rate in the
presence of incoming nucleophile.

Predict the order of reactivity of the following compounds in SN1 and E l 10.7
Example 07
SN2 reactions:
(i) The four isomeric bromobutanes
(ii) C6H5CH2Br, C6H5CH(C6H5)Br, C6H5CH(CH3)Br, C6H5C(CH3)(C6H5)Br

295 Haloalkanes and Haloarenes

NP Tips Nib
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Br
@bohring_bot
Ni i
l
z j snot
c
Nb a
far
S l ti (i) CH3CH2CH2CH2Br < (CH3)2CHCH2Br < CH3CH2CH(Br)CH3 < (CH3)3CBr (SN1)
Solution
CH3CH2CH2CH2Br > (CH3)2CHCH2Br > CH3CH2CH(Br)CH3 > (CH3)3CBr (SN2)
Of the two primary bromides, the carbocation intermediate derived from
(CH3)2CHCH2Br is more stable than derived from CH3CH2CH2CH2Br because
of greater electron donating inductive effect of (CH3)2CH- group. Therefore,
(CH3)2CHCH2Br is more reactive than CH3CH2CH2CH2Br in SN1 reactions.
CH3CH2CH(Br)CH3 is a secondary bromide and (CH3)3CBr is a tertiary
bromide. Hence the above order is followed in SN1. The reactivity in SN2
reactions follows the reverse order as the steric hinderance around the
electrophilic carbon increases in that order.
(ii) C6H5C(CH3)(C6H5)Br > C6H5CH(C6H5)Br > C6H5CH(CH3)Br > C6H5CH2Br (SN1)
C6H5C(CH3)(C6H5)Br < C6H5CH(C6H5)Br < C6H5CH(CH3)Br < C6H5CH2Br (SN2)
Of the two secondary bromides, the carbocation intermediate obtained
from C6H5CH(C6H5)Br is more stable than obtained from C6H5CH(CH3)Br
because it is stabilised by two phenyl groups due to resonance. Therefore,
the former bromide is more reactive than the latter in SN1 reactions. A
phenyl group is bulkier than a methyl group. Therefore, C6H5CH(C6H5)Br
is less reactive than C6H5CH(CH3)Br in SN2 reactions.

(c) Stereochemical aspects of nucleophilic substitution reactions
A SN2 reaction proceeds with complete stereochemical inversion while
a SN1 reaction proceeds with racemisation.
In order to understand this concept, we need to learn some basic
stereochemical principles and notations (optical activity, chirality,
retention, inversion, racemisation, etc.).
(i) Plane polarised light and optical activity: Certain compounds
rotate the plane polarised light (produced by passing ordinary
William Nicol (1768- light through Nicol prism) when it is passed through their
1851) developed the first
solutions. Such compounds are called optically active
prism that produced
plane polarised light.
compounds. The angle by which the plane polarised light is
rotated is measured by an instrument called polarimeter. If the
compound rotates the plane polarised light to the right, i.e.,
clockwise direction, it is called dextrorotatory (Greek for right
rotating) or the d-form and is indicated by placing a positive (+)
sign before the degree of rotation. If the light is rotated towards
left (anticlockwise direction), the compound is said to be laevo-
rotatory or the l-form and a negative (3) sign is placed before
the degree of rotation. Such (+) and (3) isomers of a compound
are called optical isomers and the phenomenon is termed as
optical isomerism.
(ii) Molecular asymmetry, chirality and enantiomers: The
observation of Louis Pasteur (1848) that crystals of certain
compounds exist in the form of mirror images laid the
foundation of modern stereochemistry. He demonstrated that
aqueous solutions of both types of crystals showed optical
rotation, equal in magnitude (for solution of equal concentration)
but opposite in direction. He believed that this difference in
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optical activity was associated with the three dimensional
arrangements of atoms (configurations) in two types of crystals.
Jacobus Hendricus
Dutch scientist, J. Van9t Hoff and French scientist, C. Le Bel in
Van9t Hoff (1852-1911) the same year (1874), independently argued that the spatial
received the first Nobel arrangement of four groups (valencies) around a central carbon
Prize in Chemistry in is tetrahedral and if all the substituents attached to that carbon
1901 for his work on are different, such a carbon is called asymmetric carbon or
solutions. stereocentre. The resulting molecule would lack symmetry and
is referred to as asymmetric molecule. The asymmetry of the
molecule is responsible for the optical activity in such organic
compounds.
The symmetry and asymmetry are also observed in many day to day
objects: a sphere, a cube, a cone, are all identical to their mirror images
and can be superimposed. However, many
objects are non superimposable on their
mirror images. For example, your left and
right hand look similar but if you put your
left hand on your right hand, they do not
coincide. The objects which are non-
superimposable on their mirror image (like
a pair of hands) are said to be chiral and
this property is known as chirality. While
the objects, which are, superimposable on
their mirror images are called achiral.
The above test of molecular chirality
can be applied to organic molecules by
constructing models and its mirror images
or by drawing three dimensional structures
and attempting to superimpose them in our
minds. There are other aids, however, that
can assist us in recognising chiral molecules.
One such aid is the presence of a single
asymmetric carbon atom. Let us consider
Fig 10.4: Some common examples of chiral and two simple molecules propan-2-ol and
achiral objects butan-2-ol and their mirror images.

As you can see very clearly, propan-2-ol does not contain an
asymmetric carbon, as all the four groups attached to the tetrahedral
carbon are not different. Thus it is an achiral molecule.

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Butan-2-ol has four different groups attached to
the tetrahedral carbon and as expected is chiral. Some
common examples of chiral molecules such as
2-chlorobutane, 2, 3-dihyroxypropanal, (OHC3CHOH3CH2OH),
bromochloro-iodomethane (BrClCHI), 2-bromopropanoic
acid (H3C3CHBr3COOH), etc.
Fig. 10.5: A chiral molecule The stereoisomers related to each other as non-
and its mirror image superimposable mirror images are called enantiomers
(Fig. 10.5).
Enantiomers possess identical physical properties namely, melting
point, boiling point, solubility, refractive index, etc. They only differ
with respect to the rotation of plane polarised light. If one of the
enantiomer is dextro rotatory, the other will be laevo rotatory.

However, the sign of optical rotation is not necessarily related to
the absolute configuration of the molecule.

A mixture containing two enantiomers in equal proportions will
have zero optical rotation, as the rotation due to one isomer will be
cancelled by the rotation due to the other isomer. Such a mixture is
known as racemic mixture or racemic modification. A racemic mixture
is represented by prefixing dl or ( ) before the name, for example
( ) butan-2-ol. The process of conversion of enantiomer into a racemic
x mixture is known as racemisation.

Example
E a l 10.8. Identify chiral and achiral molecules in each of the following pair of
compounds. (Wedge and Dash representations according to Class XI,
Fig 12.1).

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Solution
S ut
ut o

(iii) Retention: Retention of configuration is the preservation of integrity
of the spatial arrangement of bonds to an asymmetric centre during
a chemical reaction or transformation. It is also the configurational
correlation when a chemical species XCabc is converted into the
chemical species YCabc having the same relative configuration.

In general, if during a reaction, no bond to the stereocentre is broken,
the product will have the same general configuration of groups
around the stereocentre as that of reactant. Such a reaction is said
to proceed with retention of the configuration. Consider as an

allotted
example, the reaction that takes place when (3)-2-methylbutan-1-ol
is heated with concentrated hydrochloric acid. noBIBI
the
Bond centre

Retention pyoKI
retention
to Renfroe (iv) Inversion, retention and racemisation: There are three outcomes
for a reaction at an asymmetric carbon atom. Consider the
replacement of a group X by Y in the following reaction;

If (A) is the only compound obtained, the process is called retention
of configuration.
If (B) is the only compound obtained, the process is called inversion
of configuration.
If a 50:50 mixture of the above two is obtained then the process is
called racemisation and the product is optically inactive, as one
isomer will rotate light in the direction opposite to another.
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reactant
dord
r i
n
If notn seereport Now let us have a fresh look at SN1 and SN2 mechanisms by
taking examples of optically active alkyl halides.
In case of optically active alkyl halides, the product formed as a

start a result of SN2 mechanism has the inverted configuration as compared
to the reactant. This is because the nucleophile attaches itself on the
side opposite to the one where the halogen atom is present. When
(3)-2-bromooctane is allowed to react with sodium hydroxide,
(+)-octan-2-ol is formed with the 3OH group occupying the position
goer opposite to what bromide had occupied.

wgyopid
arg
Thus, SN2 reactions of optically active halides are accompanied by
inversion of configuration.
In case of optically active alkyl halides, S N1 reactions are
accompanied by racemisation. Can you think of the reason why it
2
happens? Actually the carbocation formed in the slow step being sp
hybridised is planar (achiral). The attack of the nucleophile may be
accomplished from either side resulting in a mixture of products, one
having the same configuration (the 3OH attaching on the same position
as halide ion) and the other having opposite configuration (the 3OH
attaching on the side opposite to halide ion). This may be illustrated
by hydrolysis of optically active 2-bromobutane, which results in the
formation of ( )-butan-2-ol.

2. Elimination reactions
When a haloalkane with -hydrogen atom is heated with alcoholic
solution of potassium hydroxide, there is elimination of hydrogen
atom from -carbon and a halogen atom from the -carbon atom.
As a result, an alkene is formed as a product. Since -hydrogen
atom is involved in elimination, it is often called -elimination.

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If there is possibility of formation of more than one alkene due to
the availability of more than one -hydrogen atoms, usually one alkene
is formed as the major product. These form part of a pattern first
observed by Russian chemist, Alexander Zaitsev (also pronounced as
Saytzeff) who in 1875 formulated a rule which can be summarised as