12th Chemistry - Vol 2 - English Medium - PDF

Summary

This chemistry textbook, part of the Tamil Nadu higher secondary second year curriculum, covers various topics in chemistry for the 12th grade. It provides explanations and examples related to topics such as Ionic Equilibrium, Electro Chemistry, Surface Chemistry, Hydroxy Compounds, and more. The book is designed for English medium students.

Full Transcript

GOVERNMENT OF TAMIL NADU

HIGHER SECONDARY SECOND YEAR

CHEMISTRY
VOLUME - II

A publication under Free Textbook Programme of Government of Tamil Nadu

Department of School Education
Untouchability is Inhuman and a Crime

Introduction Pages.indd 1 16-12-2022 19:32:16
 Government of Tamil Nadu

First Edition - 2019
Revised Edition - 2020, 2021, 2022,
2023
Reprint - 2024

(Published under new syllabus)

NOT FOR SALE

Content Creation

The wise
possess all

State Council of Educational
Research and Training
© SCERT 2019

Printing & Publishing

Tamil NaduTextbook and Educational
Services Corporation
www.textbooksonline.tn.nic.in

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 Key features …

Awareness about higher education avenues in
Scope of Chemistry
the field of Chemistry
Describe the specific competency /
Learning objectives
performance capability acquired by the learner
Additional information provided to relate the
Do you know content to day-to-day life / development in the
field
Model problems worked out for clear-cut
Example Problems
comprehension by the learners
To help the students to assess their own
Evaluate yourself
conceptual understanding
Quick access to concepts, videos, animations
Q.R code
and tutorials
opens up resources for learning; enables the
ICT learners to access, extend transform ideas /
informations

Summary A glance on the substance of the unit

Inter relating the concepts for enabling learners
Concept map
to visualize the essence of the unit
To assess the level of understanding through
Evaluation multiple choice question,numerical problems
etc…

Books for Reference List of relevant books for further reading

To help the learners confirm the accuracy of
Key answers the answers arrived and remedy the gaps in
learning
Important terms are enlisted with equivalent
Glossary
Tamil words

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 CONTENTS
CHEMISTRY

S.No. Topic Page.No. Month

8 Ionic Equilibrium 01 August

9 Electro Chemistry 33 October

10 Surface Chemistry 69 November

11 Hydroxy Compounds and Ethers 104 July

August upto
page 176.
12 Carbonyl Compounds and Carboxylic Acids 145
Remaining
september

13 Organic Nitrogen Compounds 196 October

14 Biomolecules 237 November

15 Chemistry in Everyday Life 272 November

ANSWERS 297
GLOSSARY 320

E-book Assessment

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 UNIT IONIC
8 EQUILIBRIUM

Peter Joseph William Debye Learning Objectives
After studying this unit, the students
will be able to
Peter Joseph William Debye was
’ classify the substances into acids and
Dutch-American physicist bases based on Arrhenius, Lowry –
greatly contributed to the theory Bronsted and Lewis concepts.
of electrolyte solutions. He also ’ define pH scale and establish
studied the dipole moments relationship between pH and pOH
of molecules, Debye won the ’ describe the equilibrium involved in

Nobel Prize in Chemistry the ionisation of water.
’ explain Ostwald’s dilution Law and
(1936) for his contributions
derive a relationship between the
to the determination of
dissociation constant and degree of
molecular structure through
dissociation of a weak electrolyte.
his investigations on dipole ’ recognise the concept of common ion
moments and X-rays diffraction. effect and explain buffer action.
’ apply Henderson equation for the

preparation of buffer solution
’ calculate solubility product and
understand the relation between
solubility and solubility product.
’ solve numerical problems involving

ionic equilibria.

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 INTRODUCTION

We have already learnt the chemical equilibrium in XI standard. In this unit, we discuss
the ionic equilibria, specifically acid – base equilibria. Some of the important processes in our
body involve aqueous equilibria. For example, the carbonic acid – bicarbonate buffer in the
blood.
H3O+ (aq)+HCO3- (aq)  H2CO3 (aq)+H2O(l)
We have come across many chemical compounds in our daily life among them acids and
bases are the most common. For example, milk contains lactic acid, vinegar contains acetic
acid, tea contains tannic acid and antacid tablet contains aluminium hydroxide / magnesium
hydroxide. Acids and bases have many important industrial applications. For example,
sulphuric acid is used in fertilizer industry and sodium hydroxide in soap industry etc…
Hence, it is important to understand the properties of acids and bases.
In this unit we shall learn the definitions of acids and bases and study, their ionisation in
aqueous solution. We learn the pH scale and also apply the principles of chemical equilibrium
to determine the concentration of the species furnished in aqueous solution by acids and
bases.

8.1 Acids and bases
The term ‘acid’ is derived from the latin word ‘acidus’ meaning sour. We have already
learnt in earlier classes that acid tastes sour, turns blue litmus to red and reacts with metals
such as zinc and produces hydrogen gas. Similarly base tastes bitter and turns red litmus to
blue.
These classical concepts are not adequate to explain the complete behaviour of acids and
bases. So, the scientists developed the acid – base concept based on their behaviour.
Let us, learn the concept developed by scientists Arrhenius, Bronsted and Lowry and
Lewis to describe the properties of acids and bases.
8.1.1 Arrhenius Concept
One of the earliest theories about acids and bases was proposed by swedish chemist
Svante Arrhenius. According to him, an acid is a substance that dissociates to give hydrogen
ions in water. For example, HCl, H2SO4 etc., are acids. Their dissociation in aqueous solution
is expressed as

HCl(g) 
H2 O
 H (aq)+Cl (aq)
+ -

The H+ ion in aqueous solution is highly hydrated and usually represented as H3O+ ,
the simplest hydrate of proton [H(H2O)]. We use both H+and H3O+ to mean the same.
+

Similarly a base is a substance that dissociates to give hydroxyl ions in water. For
example, substances like NaOH, Ca(OH)2 etc., are bases.
 -

HO
Ca(OH)2   Ca (aq)+2OH (aq)
2 2+

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 Limitations of Arrhenius concept
i. Arrhenius theory does not explain the behaviour of acids and bases in non aqueous solvents
such as acetone, Tetrahydrofuran etc...

ii. This theory does not account for the basic nature of the substances like ammonia ( NH3 )
which do not possess hydroxyl group.

Evaluate yourself – 1
Classify the following as acid (or) base using Arrhenius concept
i)HNO3 ii) Ba(OH)2 iii) H3PO4 iv) CH 3COOH

8.1.2 Lowry – Bronsted Theory (Proton Theory)

In 1923, Lowry and Bronsted suggested a more general definition of acids and bases.
According to their concept, an acid is defined as a substance that has a tendency to donate
a proton to another substance and base is a substance that has a tendency to accept a proton
from other substance. In other words, an acid is a proton donor and a base is a proton acceptor.

When hydrogen chloride is dissolved in water, it donates a proton to the later. Thus,
HCl behaves as an acid and H2O is base. The proton transfer from the acid to base can be
represented as
HCl+H2O  H3O+ +Cl -

When ammonia is dissolved in water, it accepts a proton from water. In this case, ammonia
( NH3 ) acts as a base and H2O is acid. The reaction is represented as

H2O+NH3  NH 4+ +OH-

Let us consider the reverse reaction in the following equilibrium

HCl + H2O  H 3 O+ + Cl -
Proton donor (acid) Proton acceptor (Base) Proton donor (acid) Proton acceptor (Base)

H3O+ donates a proton to Cl - to form HCl i.e., the products also behave as acid and base.

In general, Lowry – Bronsted (acid – base) reaction is represented as
Acid1 +Base 2  Acid 2 +Base1

The species that remains after the donation of a proton is a base (Base1 )and is called the
conjugate base of the Bronsted acid ( Acid 1 ). In other words, chemical species that differ only
by a proton are called conjugate acid – base pairs.

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 Conjugate acid - base pair

HCl + H 2O  H 3O + + Cl-
Proton donar (acid) Proton acceptor (Base) Proton donar (acid) Proton acceptor (Base)

Conjugate acid - base pair

HCl and Cl- , H 2 O and H3O + are two conjugate acid – base pairs. i.e., Cl - is the conjugate
base of the acid HCl. (or) HCl is conjugate acid of Cl-. Similarly H3O+ is the conjugate acid
of H2O.
Limitations of Lowry – Bronsted theory
i. Substances like BF3 , AlCl 3 etc., that do not donate protons are known to behave as acids.

Evaluate yourself – 2
Write a balanced equation for the dissociation of the following in water and identify
the conjugate acid –base pairs.
i) NH 4 + ii) H2SO4 iii) CH3COOH.

8.1.3 Lewis concept
In 1923, Gilbert. N. Lewis proposed a more generalised concept of acids and bases. He
considered the electron pair to define a species as an acid (or) a base. According to him, an
acid is a species that accepts an electron pair while base is a species that donates an electron
pair. We call such species as Lewis acids and bases.
A Lewis acid is a positive ion (or) an electron deficient molecule and a Lewis base is a
anion (or) neutral molecule with at least one lone pair of electrons.
Les us consider the reaction between Boron tri fluoride and ammonia
F H
F
H
F B
+ : NH3
ammonia B N
F
Boron tri fluoride F
F H
electron deficient - electron pair donar - adduct
(Lewis acid) - (Lewis base)
Here, boron has a vacant 2p orbital to accept the lone pair of electrons donated by
ammonia to form a new coordinate covalent bond. We have already learnt that in coordination
compounds, the Ligands act as a Lewis base and the central metal atom or ion that accepts a
pair of electrons from the ligand behaves as a Lewis acid.

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 Lewis acids Lewis bases

Electron deficient molecules such as Molecules with one (or) more lone pairs of
BF3 ,AlCl 3 ,BeF2 etc... electrons.
NH3 ,H2O,R-O-H,R-O-R, R - NH2

All metal ions All anions
Examples: Fe2+ ,Fe3+ ,Cr 3+ ,Cu 2+ etc... F- ,Cl - ,CN- ,SCN - ,SO2-4 etc...

Molecules that contain a polar double bond Molecules that contain carbon – carbon
Examples : SO2 ,CO2 ,SO3 etc... multiple bond
Examples: CH 2 = CH 2 , CH ≡ CH etc...

Molecules in which the central atom can All metal oxides
expand its octet due to the availability of CaO,MgO,Na 2O etc...
empty d – orbitals
Example: SiF4 ,SF4 ,FeCl 3 etc..

Carbonium ion Carbanion
(CH ) 3 3
C+ CH3−

Example

Identify the Lewis acid and the Lewis base in the following reactions.
Cr 3+ + 6 H2O → [Cr(H2O)6 ]3+
In the hydration of ion, each of six water molecules donates a pair of electron to Cr 3+
to from the hydrated cation, hexaaquachromium (III) ion, thus, the Lewis acid is Cr 3+ and
the Lewis base H2O.

Evaluate yourself – 3
Identify the Lewis acid and the Lewis base in the following reactions.

i. CaO+CO2 → CaCO3
CH3
ii. Cl
CH3 O CH3 + AlCl3 O Al Cl

CH3 Cl

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 Evaluate yourself – 4
H3BO3 accepts hydroxide ion from water as shown below
H3BO3 (aq)+H2O(l)  B(OH)4 - +H+
Predict the nature of H3BO3 using Lewis concept

8.2 Strength of Acids and Bases
The strength of acids and bases can be determined by the concentration of H3O+ (or) OH-
produced per mole of the substance dissolved in H2O. Generally we classify the acids / bases
either as strong or weak. A strong acid is the one that is almost completely dissociated in water
while a weak acid is only partially dissociated in water.
Let us quantitatively define the strength of an acid (HA) by considering the following
general equilibrium.
HA + H2O  H3O+ + A-

acid 1 base 2 acid 2 base 1

The equilibrium constant for the above ionisation is given by the following expression

[H3O+ ][A - ]
K= .....(8.1)
[HA][H2O]
We can omit the concentration of H2O in the above expression since it is present in large
excess and essentially unchanged.
[H3O+ ][A - ]
Ka = .....(8.2)
[HA]
Here, K a is called the ionisation constant or dissociation constant of the acid. It measures
the strength of an acid. Acids such as HCl,HNO3 etc... are almost completely ionised and
hence they have high K a value (K a for HCl at 25o C is 2×106 ) Acids such as formic acid
(K a =1.8 × 10-4at 25oC) , acetic acid (1.8 × 10-5at 25oC) etc.. are partially ionised in solution
and in such cases, there is an equilibrium between the unionised acid molecules and their
dissociated ions. Generally, acids with K a value greater than ten are considered as strong acids
and less than one are considered as weak acids.
Let us consider the dissociation of HCl in aqueous solution,
HCl + H - OH  H3O+ + Cl -
acid 1 base 2 acid 2 base 1

As discussed earlier, due to the complete dissociation, the equilibrium lies almost 100%
to the right. i.e., the Cl - ion has only a negligible tendency to accept a proton form H3O+. It
means that the conjugate base of a strong acid is a weak base and vice versa.
The following table illustrates the relative strength of conjugate acid – base pairs.
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 HClO4
ClO 4 -
HCl Strong Cl-
acids Very weak
H 2 SO4 - bases
HSO 4
HNO3
NO3-
H 3 O+ H 2O
HNO2 NO 2 -
Weak Weak
HF acids F- bases
CH 3COOH CH3 COO -
NH 3 NH 2 -
Strong
O 2-
OH- Very weak bases
acids H-
H2

8.3 Ionisation of water
We have learnt that when an acidic or a basic substance is dissolved in water, depending
upon its nature, it can either donate (or) accept a proton. In addition to that the pure water
itself has a little tendency to dissociate. i.e, one water molecule donates a proton to an another
water molecule. This is known as auto ionisation of water and it is represented as below...
HO - H+H 2O  H 3O + + OH -
acid 1 base 2 acid 2 base 1

Conjugate acid - base pairs

In the above ionisation, one water molecule acts as an acid while the another water
molecule acts as a base.
The dissociation constant for the above ionisation is given by the following expression
[H3O+ ][OH- ]
K= .....(8.3)
[H2O]2
The concentration of pure liquid water is one. i.e, [H 2 O]2 = 1
 K w =[H3O+ ][OH- ] .....(8.4)
Here, K w represents the ionic product (ionic product constant) of water

It was experimentally found that the concentration of H3O+ in pure water is 1×10-7 at 25oC.
Since the dissociation of water produces equal number of H3O+ and OH- , the concentration
of OH- is also equal to 1×10-7 at 25o C.

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 Therefore, the ionic product of water at 25oC is
K w =[H3O]+[OH- ]......(8.4)
K w =(1 × 10-7 )(1 × 10-7 )
= 1 × 10-14. K w values at different temperatures
Like all equilibrium constants, K w is also are given in the following below
a constant at a particular temperature. The
dissociation of water is an endothermic reaction. Temperature ( o C ) Kw
With the increase in temperature, the concentration
of H3O+ and OH - also increases, and hence the 0 1.14 × 10−15
ionic product also increases. 10 −15
2.95 × 10
In neutral aqueous solution like NaCl
solution, the concentration of H3O+ is always 25 1.00 × 10−14
equal to the concentration of OH- whereas in case 40 2.71 × 10−14
of an aqueous solution of a substance which may
behave as an acid (or) a base, the concentration of 50 5.30 × 10−14
-
H 3O + will not be equal to [OH ].
We can understand this by considering the aqueous HCl as an example. In addition to
the auto ionisation of water, the following equilibrium due to the dissociation of HCl can also
exist.
HCl+H2O  H3O+ +Cl -

In this case, in addition to the auto ionisation of water, HCl molecules also produces
H3O+ ion by donating a proton to water and hence [H3O+ ]>[OH- ]. It means that the aqueous
HCl solution is acidic. Similarly, in basic solution such as aqueous NH 3 , NaOH etc…..
[OH–]>[H3O+].
Example 8.1

Calculate the concentration of OH- in a fruit juice which contains 2 × 10-3 M, H3O+ ion.
Identify the nature of the solution.

Given that H3O+ =2 × 10-3M

K w =[H3O+ ][OH- ]
Kw 1 × 10-14
∴[OH- ]= = - =5 × 10-12 M
[H3O ] 2 × 10
+ 3

2 × 10-3 > > 5 × 10-12
i.e., [H 3O + ]>>[OH- ], hence the juice is acidic in nature

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 Evaluate yourself - 5
At a particular temperature, the K w of a neutral solution was equal to 4 × 10-14.
Calculate the concentration of [H3O+ ] and [OH- ].

8.4 The pH scale
We usually deal with acid / base solution in the concentration range 10-1 to 10-7 M. To
express the strength of such low concentrations, Sorensen introduced a logarithmic scale
known as the pH scale. The term pH is derived from the French word ‘Purissance de hydrogene’
meaning, the power of hydrogen. pH of a solution is defined as the negative logarithm of base
10 of the molar concentration of the hydronium ions present in the solution.
pH = - log 10[H3O+ ] .....(8.5)
The concentration of H 3O + in a solution of known pH can be calculated using the following
expression.
-pH
[H3O+ ]=10 (or) [H3O+ ]= antilog of (-pH) .....(8.6)

Similarly, pOH can also be defined as follows
pOH = - log 10 [OH- ] .....(8.7)
As discussed earlier, in neutral solutions, the concentration of [H3O ] as well as [OH + ] is
+

equal to 1 × 10-7 M at 25C. The pH of a neutral solution can be calculated by substituting this
H3O+concentration in the expression (8.5)
pH = - log 10 [H3O+ ]

= - log 10 10
-7

= (-7)(-1) log1010= +7 (1)= 7 [ log 1010 =1]

Similary, we can calculate the pOH of a neutral solution using the expression (8.7), it is also
equal to 7.
The negative sign in the expression (8.5) indicates that when the concentration of [H 3O + ]
increases the pH value decreases. For example, if the [H3O+ ] increases from to 10 to10 M ,
-7 -5

the pH value of the solution decreases from 7 to 5. We know that in acidic solution,
[H 3O + ] > [OH - ] , i.e., [H 3O+ ] > 10-7. Similarly in basic solution [H 3O+ ] < 10-7. So, we can
conclude that acidic solution should have pH value less than 7 and basic solution should have
pH value greater than 7.
8.4.1 Relation between pH and pOH
A relation between pH and pOH can be established using their following definitions
+
pH=-log
pH=-log10 [H
[H3O O+ ]] .....(8.5)
10 3
-
pOH = - log
pOH = - log10 [OH- ]]
[OH
10 .....(8.7)
Adding equation (8.5) and (8.7)

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 Figure 8.1 The pH scale

pH + pOH =-log10[H3O+ ]-log10 [OH- ]

(
=- log10 [H3O+ ]+log10[OH- ] )
pH+pOH =-log10[H3O+ ][OH- ] [ log a+logb = logab ]
We know that [H3O+ ][OH- ]=K w
⇒ pH+pOH= - log 10 K w
⇒ pH+pOH=pK w  pK w = −log10 K w  .....(8.8)
at 25 C, the ionic product of water, K w =1 × 10-14


pK w = - log10 10-14 = 14 log10 10
= 14
∴ (8.7) ⇒ ∴ At 25C, pH + pOH= 14

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 Example 8.2

Calculate the pH of 0.001M HCl solution
H2O + -

HCl  H3O + Cl
0.001 M 0.001 M 0.001M

H3O+ from the auto ionisation of H2O (10-7 M) is negligible when compared to the
H3O+ from 10-3M HCl.
Hence [H3O+ ] = 0.001 mol dm–3
pH=-log [H O+ ]
10 3
=-log10 (0.001)
-3
=-log10 (10 ) = 3

Note: If the concentration of the acid or base is less than 10–6 M, the concentration of
H3O+ produced due to the auto ionisation of water cannot be negleted and in such cases
[H3O+ ]=10-7 (from water) + [H3O+ ] (from the acid)
similarly, [OH- ]=10-7 M (from water) + [OH- ] (from the base)

Example 8.3

-7
Calculate pH of 10 M HCl
If we do not consider [H3O+ ] from the ionisation of H2O,
then [H3O+ ] =[HCl]=10-7 M
i.e., pH = 7, which is a pH of a neutral solution. We know that HCl solution is acidic
whatever may be the concentration of HCl i.e, the pH value should be less than 7. In this
case the concentration of the acid is very low (10-7 M) Hence, the H3O+ (10-7 M) formed
due to the auto ionisation of water cannot be neglected.
so, in this case we should consider [H3O+ ] from ionisation of H 2 O
[H3O+ ] = 10-7 (from HCl) +10-7 (from water)
= 10-7 (1+1) = 2 × 10-7
pH=-log10[H3O+ ]
=-log10 (2 × 10-7 ) = - log 2 + log 10-7 
=- log 2-(-7).log10 10
=7-log 2
=7-0.3010 = 6.6990
= 6.70

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 Evaluate yourself - 6
a) Calculate pH of 10-8 M H2SO4
B) Calculate the concentration of hydrogen ion in moles per litre of a solution whose
pH is 5.4
c) Calculate the pH of an aqueous solution obtained by mixing 50ml of 0.2 M HCl with
50ml 0.1 M NaOH

8.5 Ionisation of weak acids
We have already learnt that weak acids are partially dissociated in water and there is an
equilibrium between the undissociated acid and its dissociated ions.
Consider the ionisation of a weak monobasic acid HA in water.
HA+H2O  H3O+ +A -
Applying law of chemical equilibrium, the equilibrium constant K c is given by the
expression
[H3O+ ][A - ]
KC =
   [HA][H2O] .....(8.9)
The square brackets, as usual, represent the concentrations of the respective species in
moles per litre.
In dilute solutions, water is present in large excess and hence, its concentration may be
taken as constant say K. Further H3O+ indicates that hydrogen ion is hydrated, for simplicity
it may be replaced by H+. The above equation may then be written as,
[H+ ][A - ]
KC =
[HA] × K .....(8.10)
The product of the two constants K C and K gives another constant. Let it be K a
[H+ ][A - ]
Ka =
[HA] .....(8.11)
The constant K a is called dissociation constant of the acid. Like other equilibrium
constants, K a also varies only with temperature.
Similarly, for a weak base, the dissociation constant can be written as below.

[B+ ][OH- ]
Kb =
[BOH] ....(8.12)
8.5.1 Ostwald’s dilution law
Ostwald’s dilution law relates the dissociation constant of the weak acid (K a ) with its
degree of dissociation (α) and the concentration (c). Degree of dissociation (α) is the fraction
of the total number of moles of a substance that dissociates at equilibrium.
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 Number of moles dissociated
α=
total number of moles
We shall derive an expression for ostwald's law by considering a weak acid, i.e. acetic acid
(CH3COOH). The dissociation of acetic acid can be represented as
CH3COOH  H + + CH3COO-
The dissociation constant of acetic acid is,
[H+ ][CH3COO- ]
ka =
[CH3COOH] .....(8.13)

CH3COOH H+ CH3COO-
Initial number of
1 - -
moles
Degree of
dissociation of α - -
CH3COOH
Number of moles at
1- α α α
equilibrium
Equilibrium
(1 - α) C αC αC
concentration

Substituting the equilibrium concentration in equation (8.13)
(αC)(αC)
Ka =
(1-α)C
α 2C
Ka =
1-α .....(8.14)
We know that weak acid dissociates only to a very small extent. Compared to one, α is so
small and hence in the denominator (1 - α)  1. The above expression (8.14) now becomes,
K a = α2C
Ka
⇒ α2 =
C
Ka
α=
C .....(8.15)
Let us consider an acid with K a value 4 × 10-4 and calculate the degree of dissociation
of that acid at two different concentration 1 × 10-2 M and 1 × 10-4 M using the above expression
(8.15)
For 1 × 10-2 M ,

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 4 × 10-4
α=
10-2
= 4 × 10-2
= 2 × 10-1
= 0.2
For 1 × 10-4 M acid,
4 × 10-4
α=
10-4
=2

i.e, When the dilution increases by 100 times, (Concentration decreases from 1 × 10-2 M
to 1 × 10-4 M ), the dissociation increases by 10 times.

Thus, we can conclude that, when dilution increases, the degree of dissociation of weak
electrolyte also increases. This statement is known as Ostwald’s dilution Law.
The concentration of H+ (H3O+ ) can be calculated using the K a value as below.

[ H+ ]= α C  (Refer table).....(8.16)
Equilibrium molar concentration of [H ] is equal to αC
+

 Ka 
∴[H+ ]=  C [ equation (8.15)]
 C
K aC2
=
C
[H+ ] = K a C
.....(8.17)
Similarly, for a weak base
Kb
K b = α2C and α =
C
[OH- ] = αC
(or)
[OH- ]= K bC
.....(8.18)
Example 8.4
A solution of 0.10M of a weak electrolyte is found to be dissociated to the extent of
1.20% at 25oC. Find the dissociation constant of the acid.
1.20 K a =α2 c
Given that α=1.20%= =1.2 × 10-2
100 = (1.2 × 10-2 )2 (0.1)=1.44 × 10-4 × 10-1
= 1.44 × 10-5

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 Example 8.5

Calculate the pH of 0.1M CH3COOH solution. Dissociation constant of acetic acid is
1.8 × 10-5.

pH=-log[H+ ]
For weak acids,
[H+ ]= K a × C
= 1.8 × 10-5 × 0.1
=1.34 × 10-3M pH=-log (1.34 × 10−3 )
=3 - log1.34
= 3 - 0.1271
= 2.8729  2.87

Evaluate yourself - 7
K b for NH 4 OH is 1.8 × 10-5. Calculate the percentage of ionisation of 0.06M
ammonium hydroxide solution.

8.6 Common Ion Effect
When a salt of a weak acid is added to the acid itself, the dissociation of the weak acid is
suppressed further. For example, the addition of sodium acetate to acetic acid solution leads to
the suppression in the dissociation of acetic acid which is already weakly dissociated. In this
case, CH3COOH and CH3COONa have the common ion, CH 3COO-
Let us analyse why this happens. Acetic acid is a weak acid. It is not completely dissociated
in aqueous solution and hence the following equilibrium exists.
CH 3COOH(aq)  H + (aq)+CH 3COO- (aq)

However, the added salt, sodium acetate, completely dissociates to produce Na + and
CH3COO- ion.
CH3COONa(aq) → Na + (aq)+CH3COO- (aq)

Hence, the overall concentration of CH 3COO- is increased, and the acid dissociation
equilibrium is disturbed. We know from Le chatelier's principle that when a stress is applied
to a system at equilibrium, the system adjusts itself to nullify the effect produced by that stress.
So, inorder to maintain the equilibrium, the excess CH3COO- ions combines with H+ ions to
produce much more unionized CH 3COOH i.e, the equilibrium will shift towards the left. In
other words, the dissociation of CH3COOH is suppressed. Thus, the dissociation of a weak
acid (CH3COOH) is suppressed in the presence of a salt (CH3COONa) containing an ion
common to the weak electrolyte. It is called the common ion effect.

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XII U8-Ionic equilibrium.indd 15 16-12-2022 19:33:57
 8.7 Buffer Solution
Do you know that our blood maintains a constant pH, irrespective of a number of cellular
acid – base reactions. Is it possible to maintain a constant hydronium ion concentration in
such reactions? Yes, it is possible due to buffer action.
Buffer is a solution which consists of a mixture of a weak acid and its conjugate base (or)
a weak base and its conjugate acid. This buffer solution resists drastic changes in its pH upon
addition of a small quantities of acids (or) bases, and this ability is called buffer action. The
buffer containing carbonic acid (H2CO3 ) and its conjugate base HCO-3 is present in our
blood. There are two types of buffer solutions.
1. Acidic buffer solution : a solution containing a weak acid and its salt.
Example : solution containing acetic acid and sodium acetate
2. Basic buffer solution : a solution containing a weak base and its salt.
Example : Solution containing NH 4OH and NH 4 Cl
8.7.1 Buffer action
To resist changes in its pH on the addition of an acid (or) a base, the buffer solution should
contain both acidic as well as basic components so as to neutralize the effect of added acid (or)
base and at the same time, these components should not consume each other.
Let us explain the buffer action in a solution containing CH3COOH and CH 3COONa.
The dissociation of the buffer components occurs as below.
+
CH3COOH (aq) CH3 - COO(aq) + H3O (aq)

-

If an acid is added to this mixture, it will be consumed by the conjugate base CH3COO- to
form the undissociated weak acid i.e, the increase in the concentration of H+ does not reduce
the pH significantly.
CH3COO (aq) + H (aq) CH3COOH (aq)

If a base is added, it will be neutralized by H3O+, and the acetic acid is dissociated to
maintain the equlibrium. Hence the pH is not significantly altered.

OH (aq) + H3O+ ((aq) H2O (l)
H2O (l)
CH3COOH (aq) CH3COO (aq) + H3O+ ((aq)

OH (aq) + CH3COOH (aq) CH3COO (aq) + H2O (l)

These neutralization reactions are identical to those reactions that we have already
discussed in common ion effect.
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XII U8-Ionic equilibrium.indd 16 16-12-2022 19:33:59
 Let us analyse the effect of the addition of 0.01 mol of solid sodium hydroxide to one
litre of a buffer solution containing 0.8 M CH3COOH and 0.8 M CH3COONa. Assume that
the volume change due to the addition of NaOH is negligible. (Given: K a for CH 3COOH is
1.8 × 10-5 )

CH 3 -COOH(aq) ← 
→ CH 3COO- (aq) + H + (aq)
H2O

0.8-α α α

CH3COONa(aq) →
HO
CH3COO- (aq)+ Na + (aq)
2

0.8 0.8 0.8

The dissociation constant for CH3COOH is given by

[CH3COO- ][H+ ]
Ka = ;
[CH3COOH]
[CH3COOH]
[H+ ]=K a
[CH3COO- ]
The above expression shows that the concentration of H+ is directly proportional to
[CH3COOH].
[CH3COO- ]
Let the degree of dissociation of CH3COOH be α then,
[CH3COOH]=0.8-α and [CH3COO- ]=α+0.8
(0.8-α)
∴[H+ ]=K a
(0.8+α)
α R C NH2
The above order of reactivity can be explained in terms of
i) Basicity of the leaving group    ii) Resonance effect
(i) Basicity of the leaving group
Weaker bases are good leaving groups. Hence acyl derivatives with weaker bases as
leaving groups (L) can easily rupture the bond and are more reactive. The correct order of the
basicity of the leaving group is H2N : > : OR > RCOO : > : Cl Hence the reverse is the order
of reactivity.
(ii) Resonance effect
Lesser the electronegativity of the group, greater would
O O
be the resonance stabilization as shown below.
This effect makes the molecule more stable and reduces the R C R C
reactivity of the acyl compound. The order of electronegativity G G
of the leaving groups follows the order – Cl > - OCOR > - OR > - NH2
Hence the order of reactivity of the acid derivatives with nucleophilic reagent
follows the order
acid halide > acid anhydride > esters > acid amides
12.14.1 Nomenclature

Compound IUPAC Name
(common name, Structural formula, Prefix with position Primary Secondary
IUPAC Name) Root used
number suffix Suffix

Acetyl chloride
CH3 C Cl
ane/ oyl
– eth chloride
O
Ethanoylchloride
Propionyl chloride
C2H5 C Cl
ane/ oyl
– prop chloride
O
Propanoylchloride
Benzoyl chloride
C6H5 C Cl
ane/ oyl
– Benz chloride
O
Benzoylchloride

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XII U12-Carbonyl Compounds.indd 180 08-12-2021 22:50:47
 Acetic anhydride
CH3 C O C CH3
ane/ oic
– eth
O O anhydride
Ethanoic anhydride

Propionic anhydride
CH3 CH2 C O C CH2 CH3 oic
– prop ane/
O O anhydride
Propanoic anhydride

Benzoic anhydride
C6H5 C O C C6H5
oic
– Benz
anhydride
O O
Benzoic anhydride

Esters

Methyl acetate
CH3 C O CH3
Methyl eth ane/ oate
O
Methyl ethanoate

Ethyl acetate
CH3 C O C2H5
Ethyl eth ane/ oate
O
Ethyl ethanoate

Phenyl acetate
CH3 C O C6H5
Phenyl eth ane/ oate
O
Phenyl ethanoate

Acid Amides

Acetamide
CH3 C NH2
– eth ane/ amide
O

Ethanamide

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 Propionamide
C2H5 C NH2
– prop ane/ amide
O

Propanamide
Benzamide
C6H5 C NH2
– benz – amide
O

Benzamide

12. 14. 2. Acid Halides:
Methods of Preparation of acid chloride:
Acid chlorides are prepared from carboxylic acid by treating it with anyone of the
chlorinating agent such as SOCl2, PCl5, or PCl3
1) By reaction with thionyl Chloride (SOCl2)
O O

CH3 C OH + SOCl2 CH3 C Cl + HCl + SO2
Acetic acid Acetyl chloride

This method is superior to others as the by products being gases escape leaving the acid
chloride in the pure state.

Physical properties:
They emit pale fumes of hydrogen chloride when exposed to air on account of their
reaction with water vapour.
They are insoluble in water but slowly begins to dissolve due to hydrolysis.

Chemical properties:
They react with weak nucleophiles such as water, alcohols, ammonia and amines to
produce the corresponding acid, ester, amide or substituted amides.
1) Hydrolysis. Acyl halides undergo hydrolysis to form corresponding carboxylic acids
O O

CH3 C Cl + HOH CH3 C OH + HCl
Acetyl chloride Acetic acid

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 2) Reaction with Alcohols (Alcoholysis) gives esters.
O O

CH3 C Cl + HOC2H5 CH3 C OC2H5 + HCl
Acetyl chloride Ethyl alcohol Ethyl acetate
3) Reaction with Ammonia (Ammonolysis) gives acid amides.
O O

CH3 C Cl+ H NH2 CH3 C NH2 + HCl
Acetyl chloride Ammonia Acetamide
4) Reaction with 1o and 2o Amines gives N-alkyl amides.
O O

R C Cl+ H NHR' R C NHR' + HCl
1o amine N-alkylamide

O O

R C Cl+ H NR'2 R C NR'2 + HCl
2o amine N,N-dialkylamide

(5) Reduction.
(a) When reduced with hydrogen in the presence of ‘poisoned’ palladium catalyst, they form
aldehydes. This reaction is called Rosenmund reduction. We have already learnt this
reaction under the preparation of aldehydes
O O
Pd - BaSO4
CH3 C Cl + H 2 CH3 C H + HCl
2[H]
Acetyl chloride Acetaldehyde

(b) When reduced with LiAlH4 gives primary alcohols.
O
LiAlH4
CH3 C Cl + 4(H) CH3 CH2 OH + HCl
Ethyl alcohol

12.14.3 Acid anhydride
Methods of preparation
1. Heating carboxylic acid with P2O5
We have already learnt that when carboxylic acids are heated with P2O5 dehydration takes
place to form acid anhydride.

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 2. By reaction of acid halide with a salt of carboxylic acids.
Acid chlorides on heating with sodium salt of carboxylic acids gives corresponding
anhydride.
O O
CH3 C Cl CH3 C
Acetylchloride + O + NaCl
CH3 C O Na CH3 C
O O
Sodium acetate Acetic anhydride

Chemical properties
1. Hydrolysis
Acid anhydride are slowly hydrolysed, by water to form corresponding carboxylic acids.
O O O

CH3 C O C CH3 + H OH 2CH3 C OH
Acetic anhydride Acetic acid

2. Reaction with alcohol
Acid anhydride reacts with alcohols to form esters.
O O O O

CH3 C O C CH3 + H OC2H5 CH3 C OC2H5 + CH3 C OH

Acetic anhydride Ethylalcohol Ethyl acetate Acetic acid

3. Reaction with ammonia
Acid anhydride reacts with ammonia to form amides.
O O O O

CH3 C O C CH3 + H NH2 CH3 C NH2 + CH3 C OH
Acetamide Acetic acid
Acetic anhydride Ammonia
4. Reaction with PCl5
Acid anhydride reacts with PCl5 to form acyl chlorides.
O O O

CH3 C O C CH3 + PCl5 2CH3 C Cl + POCl3
Acetic anhydride Acetyl chloride

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 12.14.4 Esters
Methods of preparation
1. Esterification
We have already learnt that treatment of alcohols with carboxylic acids in presence of
mineral acid gives esters. The reaction is carried to completion by using an excess of reactant
or by removing the water from the reaction mixture.
2. Alcoholysis of Acid chloride or Acid anhydrides
ii) Treatment of acid chloride or acid anhydride with alcohol also gives esters
Physical Properties
Esters are colour less liquids or solids with characteristic fruity smell. Flavours of some of
the esters are given below.
S.No Ester Flavour
1 Amyl acetate Banana
2 Ethyl butyrate Pineapple
3 Octyl acetate Orange
4 Isobutyl formate Raspberry
5 Amyl butyrate Apricot

Chemical Properties
1. Hydrolysis
We have already learnt that hydrolysis of esters gives alcohol and carboxylic acid.
2. Reaction with alcohol ( Transesterification)
Esters of an alcohol can react with another alcohol in the presence of a mineral acid to
give the ester of second alcohol. The interchange of alcohol portions of the esters is termed
transesterification
O O
H+
CH3 C OC2H5 + HOC3H7 CH3 C OC3H7+ C2H5OH
Ethyl acetate Propyl acetate Ethyl alcohol
Propyl alcohol

The reaction is generally used for the preparation of the esters of a higher alcohol from
that of a lower alcohol.
3. Reaction with ammonia (Ammonolysis)
Esters react slowly with ammonia to form amides and alcohol.
O O

CH3 C OC2H5 + H NH2 CH3 C NH2 + C2H5OH
Ethyl acetate Acetamide Ethyl alcohol

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 4. Claisen Condensation
Esters containing at least one ∝- hydrogen atom undergo self condensation in the presence
of a strong base such as sodium ethoxide to form b- keto ester.
O O O O
C2H5ONa
CH3 C OC2H5 + H CH2 C OC2H5 CH3 C CH2 C OC2H5 + C2H5OH
Ethyl acetate Ethyl acetate Ethyl aceto acetate Ethyl alcohol

5. Reaction with PCl5
Esters react with PCl5 to give a mixture of acyl and alkyl chloride
O O

CH3 C OC2H5 + PCl5 CH3 C Cl + C2H5Cl + POCl3
Ethyl acetate Acetyl chloride Ethyl chloride

Evaluate yourself
Why is acid anhydride preferred to acyl chloride for carrying out acylation reactions ?
12.14.5 Acid Amides
Acid amides are derivatives of carboxylic acid in which the – OH part of carboxyl group
has been replaced by – NH2 group. The general formula of amides are given as follows.
O
Now, we shall focus our attention mainly on the study of chemistry of acetamide.
R C NH2
Methods of Preparation
1. Ammonolysis of acid derivatives
Acid amides are prepared by the action of ammonia with acid chlorides or acid anhydrides.
O O

CH3 C Cl + H NH2 CH3 C NH2 + HCl

Acetyl chloride Acetamide

O O O O
CH3 C O C CH3 + H NH2 CH3 C NH2 + CH3 C OH

Acetic anhydride Acetamide

2) Heating ammonium carboxylates
Ammonium salts of carboxylic acids (ammonium carboxylates) on heating, lose a
molecule of water to form amides.
O O

CH3 C O NH+4 CH3 C NH2 + H2O

Ammonium acetate Acetamide

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 3) Partial hydrolysis of alkyl cyanides (Nitriles)
Partial hydrolysis of alkyl cyanides with cold con HCl gives amides
Conc HCl
CH3 C N CH3 C NH2
H2O / OH
O
Methyl cyanide Acetamide
Chemical Properties
1. Amphoteric character
Amides behave both as weak acid as well as weak base and thus show amphoteric character.
This can be proved by the following reactions.
Acetamide (as base) reacts with hydrochloric acid to form salt
O O
+
CH3 C NH2 + HCl CH3 C NH3 Cl

Acetamide Acetamide hydrochloride

Acetamide (as acid) reacts with sodium to form sodium salt and hydrogen gas is liberated.
O O

2CH3 C NH2 + 2Na 2CH3 C NHNa + H2

Acetamide Sodium acetamide
2) Hydrolysis
Amides can be hydrolysed in acid or in alkaline solution on prolonged heating
O O
dil HCl
CH3 C NH2 + H2O CH3 C OH + NH4Cl

Acetamide Acetic acid
O O
NaOH
CH3 C NH2 CH3 C ONa + NH3
Acetamide Sodium acetate
3) Dehydration
Amides on heating with strong dehydrating agents like P2O5 get dehydrated to form
cyanides.
O
P2O5
CH3 C NH2 CH3 C N + H2O
Acetamide Methyl cyanide
(aceto nitrile)

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 4) Hoff mann’s degradation
Amides reacts with bromine in the presence of caustic alkali to form a primary amine
carrying one carbon less than the parent amide.
O

CH3 C NH2 + Br2 + 4 KOH CH3NH2 + K2CO3 + 2KBr + 2H2O

Acetamide Methyl amine
5) Reduction
Amides on reduction with LiAlH4or Sodium and ethyl alcohol to form corresponding amines.
O
LiAIH4
CH3 C NH2 + 4 (H) CH3 CH2 NH2 + H2O

Acetamide Ethyl amine

12.15 Uses of carboxylic acids and its derivatives
Formic acid
It is used
i) for the dehydration of hides.
ii) as a coagulating agent for rubber latex
iii) in medicine for treatment of gout
iv) as an antiseptic in the preservation of fruit juice.
Acetic acid
It is used
i) as table vinegar
ii) for coagulating rubber latex
iii) for manufacture of cellulose acetate and poly vinylacetate
Benzoic acid
It is used
i) as food preservative either in the pure form or in the form of sodium benzoate
ii) in medicine as an urinary antiseptic
iii) for manufacture of dyes
Acetyl Chloride
It is used
i) as acetylating agent in organic synthesis
ii) in detection and estimation of – OH, - NH2 groups in organic compounds
Acetic anhydride
It is used
i) acetylating agent
ii) in the preparation of medicine like asprin and phenacetin
iii) for the manufacture plastics like cellulose acetate and poly vinyl acetate.
Ethyl acetate is used
i) in the preparation of artificial fruit essences.
ii) as a solvent for lacquers.
iii) in the preparation of organic synthetic reagent like ethyl acetoacetate.

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 EVALUATION

Choose the correct answer:
1. The correct structure of the product ‘A’ formed in the reaction (NEET)
O

H2 (gas, 1 atm)
A is
Pd / C, ethanol
OH O OH OH

a) b) c) d)

2. The formation of cyanohydrin from acetone is an example of
a) nucleophilic substitution b) electrophilic substitution
c) electrophilic addition d) Nucleophilic addition
3. Reaction of acetone with one of the following reagents involves nucleophilic addition
followed by elimination of water. The reagent is
a) Grignard reagent b) Sn / HCl
c) hydrazine in presence of slightly acidic solution d) hydrocyanic acid
4. In the following reaction,
H2SO4
HC CH X Product ‘X’ will not give
HgSO4
a) Tollen’s test b) Victor meyer test
c) Iodoform test d) Fehling solution test
i) O3 NH3
5. CH2 CH2 X Y ‘Y’ is
ii) Zn / H2O
a) Formaldelyde b) di acetone ammonia
c) hexamethylene tetraamine d) oxime
6. Predict the product Z in the following series of reactions
Ethanoic acid PCl C H
→ X AnhydrousAlCl
 5
→ Y i)CH
 MgBr
ii)H O
6
→Z.
6
3
3

3
+

a) (CH3 )2C(OH)C 6 H5 b) CH3CH(OH)C 6 H5
CH2 - OH

c) CH3CH(OH)CH2 - CH3 d)

7. Assertion: 2,2 – dimethyl propanoic acid does not give HVZ reaction.
Reason: 2 – 2, dimethyl propanoic acid does not have α - hydrogen atom

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XII U12-Carbonyl Compounds.indd 189 08-12-2021 22:50:52
 a) if both assertion and reason are true and reason is the correct explanation of assertion.
b) if both assertion and reason are true but reason is not the correct explanation of
assertion.
c) assertion is true but reason is false
d) both assertion and reason are false.
8. Which of the following represents the correct order of acidity in the given compounds

a)FCH2COOH > CH3COOH > BrCH2COOH > ClCH2COOH
b)FCH2COOH > ClCH2COOH > BrCH2COOH > CH3COOH
c) CH3COOH > ClCH2COOH > FCH2COOH > Br-CH2COOH
d) Cl CH2COOH > CH3COOH > BrCH2COOH > ICH2COOH
i) NH
9. Benzoic acid ii) D
→ A 
NaOBr
3
→ B 
NaNO /HCl
→ C ‘C’ is
2

a) anilinium chloride b) O – nitro aniline
c) benzene diazonium chloride d) m – nitro benzoic acid
10. Ethanoic acid P/Br
 → 2 – bromoethanoic acid. This reaction is called
2

a) Finkelstein reaction b) Haloform reaction
c) Hell – Volhard – Zelinsky reaction d) none of these
H3 O+
→ (B)  → (C) product (C) is
11. CH3Br  → (A)  
KCN PCl 5

a) acetylchloride b) chloro acetic acid
c) α - chlorocyano ethanoic acid d) none of these
12. Which one of the following reduces tollens reagent
a) formic acid b) acetic acid
c) benzophenone d) none of these
i) Mg, ether H3O+
13. a) BrCOOH A COOH
B ‘B’ is
ii) CO2 b)
COOH COOH
a) b)

c) O
d)
c) O
C
d)
O C
14. The IUPAC name of
OH

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XII U12-Carbonyl Compounds.indd 190 08-12-2021 22:50:53
 a) but – 3- enoicacid b) but – 1- ene-4-oicacid
c) but – 2- ene-1-oic acid d) but -3-ene-1-oicacid
O

C N2H4
15. Identify the product formed in the reaction CH3
C2H5 ONa

a) b)
NH2

C) d)
O

C
O - C2H5

16. In which case chiral carbon is not generated by reaction with HCN
O
OH

a) b)

O
O O

C) d)

Ph Ph

   OH

17. Assertion : p – N, N – dimethyl aminobenzaldehyde undergoes benzoin condensation
Reason : The aldehydic (-CHO) group is meta directing
a) if both assertion and reason are true and reason is the correct explanation of assertion.
b) if both assertion and reason are true but reason is not the correct explanation of assertion.
c) assertion is true but reason is false d) both assertion and reason are false.
18. Which one of the following reaction is an example of disproportionation reaction
a) Aldol condensation b) cannizaro reaction
c) Benzoin condensation d) none of these
19. Which one of the following undergoes reaction with 50% sodium hydroxide solution to
give the corresponding alcohol and acid
a) Phenylmethanal b) ethanal c) ethanol d) methanol

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XII U12-Carbonyl Compounds.indd 191 08-12-2021 22:50:53
 20. The reagent used to distinguish between acetaldehyde and benzaldehyde is
a) Tollens reagent b) Fehling’s solution
c) 2,4 – dinitrophenyl hydrazine d) semicarbazide
21. Phenyl methanal is reacted with concentrated NaOH to give two products X and Y. X
reacts with metallic sodium to liberate hydrogen X and Y are
a) sodiumbenzoate and phenol b) Sodium benzoate and phenyl methanol
c) phenyl methanol and sodium benzoate d) none of these
22. In which of the following reactions new carbon – carbon bond is not formed?
a) Aldol condensation b) Friedel craft reaction
c) Kolbe’s reaction d) Wolf kishner reduction
23. An alkene “A” on reaction with O3 and Zn - H2O gives propanone and ethanal in equimolar
ratio. Addition of HCl to alkene “A” gives “B” as the major product. The structure of product “B” is
CH3 CH2Cl

a) Cl CH2 CH2 CH b) H3C CH2 CH CH3

CH3
CH3 CH3

c) H3C CH2 C CH3 d) H3C CH CH

Cl Cl

24. Carboxylic acids have higher boiling points than aldehydes, ketones and even alcohols of
comparable molecular mass. It is due to their (NEET)
a) more extensive association of carboxylic acid via van der Waals force of attraction
b) formation of carboxylate ion
c) formation of intramolecular H-bonding
d) formation of intermolecular H – bonding
Short Answer Questions
1. How is propanoic acid is prepared starting from
(a) an alcohol (b) an alkylhalide (c) an alkene
2. A Compound (A) with molecular formula C 2 H3 N on acid hydrolysis gives(B) which
reacts with thionylchloride to give compound(C). Benzene reacts with compound (C) in
presence of anhydrous AlCl 3 to give compound(D). Compound (D) on reduction with
Zn/Hg and Conc.HCl gives (E). Identify (A), (B), (C), (D) and (E). Write the equations.
3. Identify X and Y.
+
CH3COCH2CH2COOC 2 H5 CH
MgBr
→ X H
3O
→Y 3

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XII U12-Carbonyl Compounds.indd 192 08-12-2021 22:50:54
 4. Identify A, B and C
PCl5 Benzene
benzoic acid A B
Anh