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NCERT Solutions For Class 11 Chemistry Chapter 8 Redox Reactions Multiple Choice Questions

Question 1. Oxidation numbers of S in peroxonosulphric and peroxonosulphric acids respectively are-

1. +3 and +3
2. +4 and +6
3. +6 and +6
4. +8 and +7

Answer: 2. +4 and +6

Question 2. The oxidation number of pyrophosphoriqaeid is-

1. +1
2. +3
3. +4
4. +5

Answer: 4. +5

Question 3. When SO₂ gas is passed through an acidic solution of K₂Gr₂O₇, the oxidation number of S changes by

1. 2 unit
2. 3 unit
3. 4 unit
4. 6 unit

Answer: 1. 2 unit

Redox Reactions Class 11 Multiple Choice Questions

Question 4. When manganous salt is fused with KNO₃ and solid NaOH, the oxidation number changes from

1. +2 to +3
2. +2 to +4
3. +2 to +6
4. +2 to +7

Answer: 3. +2 to +6

Question 5. Which ofthe following reactions is not a redox reaction

1. 2CuSO₄ + 4KI→ Cu₂I₂ + 2K₂SO₄ + I₂
2. SO₂ + H₂O→H₂SO₃
3. CuSO₄ + 4NH₃→ [Cu(NH₃)4]SO₄
4. 4KClO₃ →3KC1O₄ + KCl

Answer: 3. CuSO₄ + 4NH₃→ [Cu(NH₃)4]SO₄

Question 6. Which of the following reactions does the reaction, Ag²⁺ + Ag→Ag⁺, belong to

1. Reduction
2. Oxidation
3. Comproportionation
4. Disproportionation

Answer: 3. Comproportionation

Question 7. In the following reaction, the oxidation half-reaction gives, 2KMnO₄ + 5H₂C₂O₄ + 3H₂SO₄ →  K₂SO₄ + 2MnSO₄+ 10CO₂ + 8H₂O

1. MnSO₄
2. CO₂
3. K₂SO₄
4. H₂O

Answer: 2. CO₂

Question 8. The amount of electrons required to reduce 1 mol of nitrate ions to hydrazine is-

1. 7 mol
2. 6 mol
3. 5 mol
4. 4 mol

Answer: 1. 7 mol

Question 9. The reaction of ClO₂ with H₂O₂ in an alkaline medium results in O₂ and Cl^– ions. In this reaction, ClO₂ acts as an oxidant. The number of mol of H₂O₂ oxidized by 1 mol of ClO₂ is

1. 1.0
2. 1.2
3. 2.5
4. 2.8

Answer: 3. 2.5

Question 10. In the balanced equation of the reaction,

⇒  \(\mathrm{Zn}+\mathrm{NO}_3^{-}+\mathrm{OH}^{-} \rightarrow \mathrm{ZnO}_2^{2-}+\mathrm{NH}_3\), the coefficients of Zn, NO₃ and OH^– respectively are—

1. 1,4 and 8
2. 8,3 and 2
3. 4,1 and 7
4. 5,2 and 8

Answer: 3. 4,1 and 7

NCERT Solutions Class 11 Chemistry Chapter 8 Redox Reactions MCQs

Question 11. The amount of iodine that liberates in the reaction of 0.1 mol of K₂Cr₂O? with an excess of K₃ in an acidic solution is

1. 0.1 mol
2. 0.2 mol
3. 0.3 mol
4. 0.4 mol

Answer: 3. 0.3 mol

Question 12. In a strong alkaline solution, the equivalent mass of KMnO₄ (molecular mass =M) is—

1. M/5
2. M/2
3. M/2
4. M

Answer: 4. M

Question 13. In the balanced equation for the reaction,

⇒ \(\mathrm{As}_2 \mathrm{~S}_3+a \mathrm{ClO}_3^{-}+b \mathrm{OH}^{-}\) →  \(x \mathrm{AsO}_4^{3-}+y \mathrm{ClO}^{-} \div z \mathrm{SO}_4^{2-} \div 6 \mathrm{H}_2 \mathrm{O}\) the values of a and b respectively are-

1. 3 and 7
2. 8 and 3
3. 5 and 2
4. 6 and 8

Answer: 2. 8 and 3

Question 14. In the reaction of KMnO₄ with ferrous ions in an acidic medium, KMnO₄ oxidizes ferrous ions to ferric ions and itself gets reduced to manganous salt. The number of ferrous ions oxidized by 100 mL of 0.2(N) KMnO₄ solution is

1. 1.117 g
2. 1.562 g
3. 2.173 g
4. 1.934 g

Answer: 1. 1.117 g

Question 15. The oxidation number of B in NaBH₄ is 

1. -3
2. +3
3. +2
4. -4

Answer: 2. +3

Question 16. The equivalent mass of the oxidant in the reaction, 3Cl₂ + 6NaOH→5NaCl + NaClO₃ + 3H₂O is

1. 71
2. 14.2
3. 7.1
4. 35.5

Answer: 3. 7.1

Question 17. \(\mathrm{Cr}(\mathrm{OH})_3+\mathrm{IO}_3^{-}+\mathrm{OH}^{-} \rightarrow \mathrm{CrO}_4^{2-}+\mathrm{H}_2 \mathrm{O}+\mathrm{I}_2\) In the balanced equation of this reaction, the coefficient of H₂O is-

1. 2
2. 3
3. 4
4. 5

Answer: 4. 5

Question 18. In the balanced equation for the reaction-

⇒ \(\mathrm{As}_2 \mathrm{~S}_3+a \mathrm{ClO}_3^{-}+b \mathrm{OH}^{-}\)→ \( x \mathrm{AsO}_4^{3-}+y \mathrm{ClO}^{-}+z \mathrm{SO}_4^{2-}+6 \mathrm{H}_2 \mathrm{O}\)

1. x+y+z=a
2. a+x+z=b
3. a-x-z=y
4. b-a=y-z

Answer: 2. a+x+z=b

Class 11 Chemistry Chapter 8 Redox Reactions MCQs NCERT Solutions

Question 19. In the reaction, Fe₃O₄ + KMnO₄ → Fe₂O₃ +MnO₂, the equivalent mass of Fe₃O₄ is

1. 116
2. 232
3. 773
4. 154.6

Answer: 2. 232

Question 20. Which of the following requires an oxidant

1. Cu²⁺→ Cu

2. Cu₃P₂→2PH₃

3. \(2 \mathrm{~S}_2 \mathrm{O}_3^{2-} \rightarrow \mathrm{S}_4 \mathrm{O}_6^{2-}\)

4. \(\mathrm{SO}_3 \rightarrow \mathrm{SO}_4^{2-}\)

Answer: 3. \(2 \mathrm{~S}_2 \mathrm{O}_3^{2-} \rightarrow \mathrm{S}_4 \mathrm{O}_6^{2-}\)

Question 21. In the presence of HCl(aq), K₂Cr₂O₇ oxidizes tin (Sn) into Sn⁴⁺ ions. The amount of that will be oxidisedby1 mol K₂Cr₂O₇ is 

1. 1.0 mol
2. 1.5 mol
3. 2.0 mol
4. 2.5 mol

Answer: 2. 1.5 mol

NCERT Redox Reactions MCQs for Class 11

Question 22. The amount of Na₂S₂O₃ required for reducing iodine produced by the reaction of mol ofKI with H₂O₂ in an acid medium is

1. 0.5 mol
2. 1 mol
3. 2 mol
4. 2.5 mol

Answer: 3. 2 mol

Question 23. The ratio of equivalent masses of KMnO₄ in acidic, strong alkaline, and neutral solutions is

1. 3:5:15
2. 3:15:5
3. 5:5:3
4. 3:3:5

Answer: 2. 3:15:5

Question 24. The amount of H₂O₂ required for decolorizing 1 mol of KMnO₄ in an acid solution is

1. 1.5 mol
2. 2.0 mol
3. 2.5 mol
4. 3.0 mol

Answer: 3. 2.5 mol

Question 25. Fe has the lowest oxidation state in

1. FeSO₄(NH₄)₂SO₄.6H₂O
2. K₄[Fe(CN)g]
3. Fe(CO)₅
4. Fe_0.94O

Answer: 3. Fe(CO)₅

Question 26. A compound of Xe and F is found to have 53.5% Xe. What is the oxidation number of Xein in this compound?

1. -4
2. 0
3. +4
4. +6

Answer: 4. +6

Multiple Choice Questions on Redox Reactions Class 11 Chemistry

Question 27. A disproportionation reaction is not possible for

1. ASH₃
2. SF₄
3. H₅IO₆
4. PCl₃

Answer: 3. PCl₃

Question 28. When lmol of KClO₃ accepts 4 t nol of electrons, the expected product is

1. ClO^–₂
2. ClO^–₄
3. OCl^–
4. Cl^–

Answer: 3.  OCl^–

Question 29. \(\mathrm{M}^{x+}+\mathrm{MnO}_4^{-} \rightarrow \mathrm{MO}_3^{-}+\mathrm{Mn}^{2+}+\frac{1}{2} \mathrm{O}_2\) If 1 mol of MnO₄ oxidises 2.5 mol of M-v+, then the value of X is 

1. 5
2. 3
3. 4
4. 1

Answer: 4. 1

Redox Reactions MCQs Chapter 8 Class 11 NCERT

Question 30. During the reaction between KClO₃ and (COOH)₂ in an acidic medium, the tire element that undergoes a maximum change in the oxidation number is

1. K
2. O
3. Cl
4. C

Answer: 3. Cl

Question 31. If the oxidation numbers of Cr in CrOg, K₂CrO₄  K,Cr₂O^– and [Cr(NH₃)₄Cl₂]Cl are +a, +b, +c and +d respectively, then

1. a>c>b>d
2. a=x>b>d
3. a=b>c>d
4. a=b=c>d

Answer: 2. a=x>b>d

Question 32. The oxidation number of Pt in [Pt(C₂H₄)Cl₃]^– is

1. +3
2. +4
3. +2
4. O

Answer: 3. +2

Question 34. For the reaction:

⇒  \(\mathrm{H}_2 \mathrm{O}_2+x \mathrm{ClO}_2 \rightarrow x \mathrm{Cl}^{-}+y \mathrm{O}_2+\mathrm{H}_2 \mathrm{O}\) the value of y/x is

1. 2.0
2. 2.5
3. 1.0
4. 1.5

Answer: 2. 2.5

Question 35. The oxidation number of Ba(H₂PO₂)₂ is

1. +3
2. +2
3. +1
4. -1

Answer: 3. +1

Question 36. \(a \mathrm{Mn}^{2+}+b \mathrm{BiO}_3^{-}+c \mathrm{H}^{+}=\mathrm{I}^{-} \mathrm{MnO}_4^{-}+b \mathrm{Bi}^{3+}+d \mathrm{H}_2 \mathrm{O}\)

1. a = 3
2. b = 5
3. c =10
4. d = 6

Answer: 2. b = 5

NCERT Class 11 Redox Reactions MCQs

Question 37. The mixture of NaOH solution and white P on heating produces PH₃ gas and Na₂H₂PO₂. The above reaction is an example of

1. Oxidation reaction
2. Reduction reaction
3. Comproportionation reaction
4. Disproportionation reaction

Answer: 4. Disproportionation reaction

Question 38. For the reaction:

⇒ \(\mathrm{Zn}(\mathrm{s})+\mathrm{HNO}_3(a q) \longrightarrow\) \(\mathrm{Zn}\left(\mathrm{NO}_3\right)_2(a q)+\mathrm{NH}_4 \mathrm{NO}_3(a q)+\mathrm{H}_2 \mathrm{O}(l)\)

The change in oxidation number per mole HNO₃ is

1. Increases by 6 unit
2. Decreases by 4 unit
3. Decreases by 8 unit
4. Decreases by 6 unit

Answer: 3. Decreases by 8 unit

Question 39. To balance the chemical equation

⇒ \(\mathrm{Cl}_2 \mathrm{O}_7(\mathrm{~g})+\mathrm{H}_2 \mathrm{O}(l)+x e \rightarrow \mathrm{ClO}_2^{-}(a q)+\mathrm{OH}^{-}(a q)\) the value of x should be-

1. 8
2. 6
3. 5
4. 4

Answer: 2. 6

Class 11 Chemistry Redox Reactions Multiple Choice Questions

Question 40. Find the equivalent mass of Na₂S₂O₃ for the reaction

⇒ \(2 \mathrm{Na}_2 \mathrm{~S}_2 \mathrm{O}_3(a q)+\mathrm{I}_2(\mathrm{~s}) \rightarrow \mathrm{Na}_2 \mathrm{~S}_4 \mathrm{O}_6(a q)+\mathrm{NaI}(a q)\)

[Assume that the molecular mass of Na₂S₂O₃ is M]

1. M/8
2. M
3. M/2
4. M/4

Answer: 2. M

CBSE Class 11 Chemistry Notes For Chapter 5 States Of Matter Gases And Liquids States Of Matter Gases And Liquids Introduction

Anything that possesses mass and occupies space is called matter. Based on physical state, they can be of three types i.e., solid, liquid, and gas. Any substance can exist in any one ofthe three states, depending on the temperature and pressure.

Along with these three states, matter can exist in two other states.

They are plasma and Bose-Einstein condensate. However, the physical state of a substance at normal temperature (usually 25°C) and pressure {i.e. 1 atm) depends on its normal melting point and normal boiling point.

• A substance is said to be in a gaseous state if its normal boiling point is below room temperature.
• According to kinetic molecular theory, matter is composed of minute particles (like atoms, molecules, or ions), which are held together by intermolecular forces of attraction.
• However, particles of matter also possess thermal energy due to temperature.
• The forces arising from thermal energy have a disruptive effect and tend to cause the particles to get separated from each other.

Read and Learn More CBSE Class 11 Chemistry Notes

Thus, the effect of intermolecular forces of attraction and that of thermal energy are just opposite, and they counteract each other.

• The relative magnitudes of those counteracting effects determine whether a substance would exist in a solid, liquid, or gaseous state at a given temperature and pressure.
• If the effect of intermolecular forces of attraction is much less than that of the thermal energy of the molecules in a substance, then the substance exists in the gaseous state.
• Because intermolecular forces of attraction in a gas are very weak or negligible, gas molecules do not occupy fixed positions.
• Instead, they are always in ceaseless, rapid, and random motion, and move out independently throughout the entire volume ofthe container holding the gas.
• This explains why gases do not have any definite shape or volume.

When the effect of intermolecular forces of attraction is comparatively greater than that of the thermal energy of the molecules of a substance, then the substance exists in the liquid state.

• Because intermolecular forces attract liquids that are not so strong for their molecules to be held at well-defined positions, liquids do not have a definite shape.
• They assume the shape of the container in which they are kept.
• However, intermolecular forces of attraction in a liquid are strong enough to hold the molecules together and prevent them from moving apart. This is why liquids have a definite volume.
• When the effect of intermolecular forces of attraction is much stronger compared to that of thermal energy in a substance, then the substance exists in a solid state.
• In a solid due to strong intermolecular forces of attraction, particles in I Solid state making up the solid are held at fixed locations and remain very close to each other.

Particles, being held at fixed positions, do not possess translational motion although they can vibrate about their mean positions. As the particles in a solid have fixed positions and lack translational motion, solids have a definite shape and volume.

NCERT Class 11 Chemistry Notes Liquids, States of Matter, Gases

Various Kinds Of Intermolecular Attractive Forces And Their Nature

Attractive Forces Acting Between The molecules (atoms in the case of monoatomic gas) in a substance are called intermolecular forces of attraction.

These forces are different from the electrostatic force existing between the two oppositely charged ions and the forces that hold the atoms together with molecular covalent bonds intermolecular forces of attraction are relatively weaker than the forces of attraction by which atoms are held in covalent bonds or the electrostatic forces of hydrogen by which oppositely charged ions are held.

Different Types Of Intermolecular Forces of Attraction

Intermolecular forces of attraction are classified as follows:

1. Instantaneous induced dipole-instantaneous induced dipole attractions.
2. Dipole-dipole attractions.
3. Dipole-induced dipole attractions
4. Ion-dipole attractions
5. Hydrogen bond. Among the above forces, the first three are collectively known as the van der Waals forces because van der Waals explained the deviation of real gases from ideal behaviour in terms of these forces. In this chapter, we will focus only on the van der Waals forces.

Instantaneous induced dipole-instantaneous induced dipole attraction (London forces or dispersion forces)

These forces are found to occur in all substances because they exist between all atoms, molecules, and ions. In the case of non-polar substances, however, these are the only intermolecular forces that operate.

Due to the existence of these forces, it is possible to transform non-polar gases (such as H₂, N₂, O₂, CH₄, etc.) or inert gases (such as He, Ne, Ar, etc.) into liquid, when cooled to very low temperatures.

These forces are commonly known as London forces, after the name of a German physicist. Frit London, explained the origin and nature of these forces.

Origin:

To understand the origin of London forces, let us consider the generation of a dipole in an atom. Electrons are symmetrically distributed around the nucleus of an atom.

This symmetrical distribution is a time average distribution and the centers of gravity of the positive charge and negative charge (electron cloud) remain at the same point in this distribution.

However, at any instant, the density of the electron cloud on one side of the nucleus may be greater than the other.

Consequently, an instantaneous dipole develops in the die atom due to the separation of charge centers and as a result, a partial negative charge (O’-) on one side ofthe atom and a partial positive charge (5+) on the other side are created.

This short-lived dipole continuously changes its direction with the movement of electrons in such a way that the time average dipole moment becomes zero. The instantaneous dipole formed in one atom distorts the symmetrical distribution of the electron cloud of a neighbouring atom and induces an instantaneous dipole in that atom.

Similar temporary dipoles are induced in polar molecules also. This leads to an interatomic or intermolecular attraction. Such forces of attraction are known as instantaneous-induced dipole-instantaneous induced dipole attraction. Illustrates how instantaneous induced dipole-instantaneous induced dipole forces develop between the atoms in He gas.

Characteristics:

1. The strength of London forces decreases very rapidly as the distance between particles increases. If the distance between two interacting particles is r then the strength of London forces varies as 1/r6.
2. The strength of this force generally lies between 0.05 to 40 kj.mol-1
3. The magnitude of London’s force depends on the polarisability ofthe atoms or molecules. The polarisability of an atom or a molecule is a measure of the ease with which its electron clouds can be distorted.

An atom or a molecule with a large size (or large molar mass) contains a large number of electrons and hence possesses a large diffused electron cloud, which can get distorted easily. This is why atoms or molecules with larger size (or molar mass) are more polarisable and found to possess stronger London forces.

For the halogens, molecular sizes follow the order: F₂ < Cl₂ < Br₂ < I₂:

Accordingly, the order of their increasing strength of London forces is F, < Cl, < Br₂ < I₂. Because of this, their boiling points follow the order F₂ < Cl₂ < Br₂< I₂ Similarly, the order of boiling points of inert gases is He < Ne < Ar < Kr < Xe. This is because the atomic size of inert gases increases in die same order.

Dipole-dipole attraction

These forces exist between neutral polar molecules (Example: H₂O, NH₃, HC₁, etc.). However, in addition to these forces, London forces also act between the molecules.

Origin:

Polar molecules have permanent dipoles.

• They possess a partial positive charge at one end and a partial negative charge at the other end.
• The dipole-dipole attractive force causes the polar molecules to align themselves in such a manner that the positive end of one polar molecule is directed towards the negative end of another polar molecule.
• As a result, a net attractive force acts between the two polar molecules.

This attractive force is called the dipole-dipole attractive force.

Dipole-dipole attraction Characteristics:

1. Dipole-dipole attractive forces are generally stronger than London forces and have a magnitude ranging from 5-25 kj.mol^-1
2. The strength of dipole-dipole attractive forces increases with the increasing polarity of the molecules
3. As the distance between the two dipolar molecules increases, the strength of these forces decreases. If the distance between two dipoles is r, then dipole-dipole attractive forces will be proportional to l/r6.

Dipole-induced dipole attractions

These forces act between polar molecules having permanent dipole moments and non-polar molecules or polar molecules having very low dipole moments. For example— H₂O….I₂, Kr….(phenol)₂, etc.

Origin:

Whenever a polar molecule comes closer to a polarisable non-polar molecule, the polar molecule induces a dipole moment in the non-polar molecule by deforming or polarising its electron cloud.

Thus, the non-polar molecule becomes a dipole. We call it an induced dipole as it is induced by the polar molecule. As a result, attractive forces are generated between the permanent dipole and the induced dipole. This attractive force is called dipole-induced dipole attractive force.

Dipole-induced dipole attractions Characteristics:

1. If the distance between the molecule with a permanent dipole and that with an induced dipole is r, then the dipole-induced dipole attractive force between them is found to be proportional to 1/r6.
2. The strength of this force increases with the increasing dipole moment of a polar molecule and the polarisability of a non-polar molecule.
3. The magnitude of this force is generally 2-10 kj.mol^-1.

Physical And Measurable Properties Of Gaseous Substances

The physical properties of different gaseous substances are generally the same although their chemical properties may differ Some important properties

The physical properties of a gas can be explained with the help of four measurable properties such as pressure, temperature, mass, and volume. Different gas laws are based on the relationships among these properties.

Mass And Volume Of Gas

• Mass of gas:  The mass of a gas enclosed in a container can be determined by subtracting the mass of the empty container from the mass of the container filled with the gas. In the gas laws, the amount of a gas is generally expressed in terms of moles. The number of moles of a gas enclosed in a container is obtained by dividing the mass of the gas by its molar mass.
• Volume of a gas: At a particular temperature and pressure, the volume of a gas enclosed in a container is equal to the volume ofthe container
• Units of volume: Generally, volume is expressed in the (L), millilitre (mL), cubic centimetre (cm³), cubic meter (m³), or cubic decimetre (dm³).

The relationship among these different units are—

⇒ \(1 \mathrm{~L}=10^3 \mathrm{~mL}=10^3 \mathrm{~cm}^3=10^3 \times\left(10^{-1}\right)^3 \mathrm{dm}^3=1 \mathrm{dm}^3\)

In the SI system, the unit of volume is a cubic meter (m3).

⇒ \(1 \mathrm{~m}^3=\left(10^2 \mathrm{~cm}\right)^3=10^6 \mathrm{~cm}^3=10^6 \mathrm{~mL}=10^3 \mathrm{dm}^3=10^3 \mathrm{~L}\)

The pressure of a gas

The pressure of a gas arises due to the collisions of the gas molecules with the walls of the container in which it is kept. It is defined as the force exerted by the gas molecules per unit area ofthe walls of the container.

Measurement of atmospheric pressure:

Atmospheric pressure is measured with the help of an apparatus known as a barometer To construct a barometer, a glass tube, about 80 cm long, with one end closed is filled with dry mercury.

• And placed vertically with its open end immersed in a dish of mercury. As some mercury lows out of the tube, the height of the mercury level in the tube drops gradually.
• This continues until the downward pressure exerted by the mercury column and the atmospheric pressure over the mercury in the dish become equal.
• When the mercury level inside the tube becomes fixed, it is nd placed vertically with its open end immersed in a dish of mercury. As some mercury lows out of the tube, the height of the mercury level in the tube drops gradually.
• This continues until the downward pressure exerted by the mercury column and the atmospheric pressure over the mercury in the dish become equal.

When the mercury level inside the tube becomes fixed, it is

• Inside The Tube Is a Perfect Vacuum, The Pressure is Due To The. Mercury Column Is Equal To The Pressure Of The Atmosphere.
• Thus, The Height Of The Mercury Level In The Barometer Tube Is
• A Direct Measure Of The Atmospheric Pressure.
• For This Reason, Atmospheric Pressure Is Usually Expressed In
• Terms Of Height Of The Mercury Level In The Barometer Tube. For Example, The Atmospheric Pressure Of 76 Cm (Or 760 Mm) Hg Means That The Atmospheric Pressure Is Equal To The Pressure Exerted By 76 Cm (Or 760 Mm) mercury column.

The pressure exerted by the mercury column:

Let us consider a mercury column of hem height in a glass tube with a uniform cross-sectional area of Acm². The downward force exerted by the mercury column is equal to its weight, and this force per unit area is the pressure exerted by the column.

Therefore, the pressure exerted by the mercury column,

P = \(\frac{\text { force }}{\text { area }}=\frac{\text { mass } \times \text { acceleration due to gravity }}{A}=\frac{m \times g}{A}\)

Where m and g are the mass of the mercury inside the tube and acceleration due to gravity respectively. If the volume and density of mercury inside the tube are V and d, respectively,

Then- V=  A × h and m = V × d = A × h × d

And,

P = \(\frac{m \times g}{A}=\frac{A \times h \times \mathrm{d} \times g}{A}\)

• By using equation (1), we can calculate the pressure exerted by a mercury column of height if the density (d) of mercury and the acceleration due to gravity (g) is known of a place depending on the height of that place from the sea level.
• The higher the altitude, the lower the atmospheric pressure. Atmospheric pressure also depends on the temperature and weather conditions.
• The pressure exerted by a mercury column of 76 cm or 760 mm height at sea level is defined as the standard or normal atmospheric pressure.

Determination of the pressure of gas:

The instrument used for measuring the pressure of a gas in a vessel is called a manometer. Using this instrument, the pressure of gaseous reactants or products in a chemical reaction can be measured. Manometers are of two types: open-end manometers and closed-end manometers.

Open-end manometer:

It consists of aU-tube partly filled with mercury. One arm ofthe tube is longer than the other. The shorter arm is connected to a container holding a gas whose pressure is to be determined. The longer arm is open to the atmosphere, Three possibilities may arise during the determination of the pressure of a gas using such a manometer.

• The level of mercury in both the arms of the U-tube is the same. Therefore, the pressure of the gas enclosed in the bulb is equal to the atmospheric pressure, i.e., P_gas = P_atm. 
• The level of mercury in the longer arm of the U-tube is above that in the shorter arm. This occurs when the pressure of the gas inside the bulb is greater than the atmospheric pressure i.e., P_gas >P_atm. 
• The pressure of the gas = atmospheric pressure + difference between the heights of mercury levels in the two arms of the  U-tube i.e., P_gas = P_atm. 
• The level of mercury in the longer arm is below that in the shorter arm, indicating the pressure of the gas inside the bulb is less than the die atmospheric pressure i.e., P_gas < P_atm. 
• Therefore, the pressure of the gas = atmospheric pressure – the difference between the heights of mercury levels in the two arms of the tube, ie., Psas = Paatmh

Closed-end manometer:

If the pressure of the gas inside the die container is less than the die atmospheric pressure, then this type of manometer is generally used to determine the pressure of the gas.

• It also consists of a U-tube with arms of different heights, The space above the mercury level ofthe closed-end arm of the U-tube is made perfectly vacuum by partially filling up the tube with mercury.
• The shorter arm is connected to the container filled with gas whose pressure is to be determined.

Because of the pressure exerted by the gas, the mercury level goes down in the shorter arm and goes up in the longer arm. The difference between the mercury levels in the two arms gives the pressure of the gas.

Therefore, the pressure of the gas= The difference between the mercury levels in the two arms = h i.e., P_gas= h

Units of pressure:

1. The pressure of a gas is generally expressed in the unit of the atmosphere (atm). The pressure exerted by exactly 76 cm (or 760 mm) of a mercury column at the level of 0°C is called 1 atmosphere (1 atm).

2. Sometimes, pressure is also expressed in torr [named after Torricelli], The pressure exerted by exactly 1 mm of mercury column at sea level at 0°C is called 1 torr.

1 atm = 760 torr

The value of 1 atm pressure in torma of dyn/cm² and N/m²:

At 0°C, the density of pure mercury, d = 13.5951 g. cm^-3, standard acceleration due to gravity, g =9110.665 cm. s¯³; height of mercury column, h = 76cm.

Applying the relation P = h × d × g gives,

1 atm =76 cm × 13.5951 g cm¯³ ×  980.665 cm. s¯²

= 1.013 × 10⁶ dyn cm¯² [∴ dyn = g. cm. s¯²)

= 1.013 × 10⁵ N m‾²

1N = 10⁵ dyn and 1m = 100 cm]

The SI unit of pressure is Pascal.

3. The pressure exerted when a force of 1 newton acts on an area of lm² is called 1 pascal. Therefore,[1 Pa = 1 N m‾²J, and 1 atm

= 1.013 ×10⁵ N.m² = 1.013 ×10⁵ Pa

= 101.3 kPa

1 atm = 76.0 cm Hg = 760 mm Hg = 760 torn = 1.013 × 10⁵ N m^-2

= 1.013 × 10⁵ Pa Another unit used for gas pressure is a bar.

1 bar = 105 Pa = 0.9869 atm = 750.062 torr and atm = 1.013 bar

The pressure is also expressed in the unit pound per square inch or psi. 1 atm = 14.7 psi

Numerical Examples

Question 1. At a certain place, the atmospheric pressure is 740 mm Hg. What will be the value of this pressure in the units of— torr atm Pa and bar
Answer: Given:

Atmospheric pressure = 740 mm Hg.

1 torr =1 mm Hg.

Therefore, 740 mm Hg = 740 torr

1 atm = 760 mm Hg

Thus, 740 mm Hg \(=\frac{1 \mathrm{~atm}}{760 \mathrm{~mm} \mathrm{Hg}} \times 740 \mathrm{~mm} \mathrm{Hg}\)

= 0.97 atm

Atm = 760 mm Hg = 1.013 X 105 Pa

Therefore, 740mm Hg \(=\frac{1.013 \times 10^5 \mathrm{~Pa}}{760 \mathrm{~mm} \mathrm{Hg}} \times 740 \mathrm{~mm} \mathrm{Hg}^{-10}\)

= 9.86 ×10⁴ Pa

1 atm = 760 mm Hg

= 1.013 bar

Hence, 740 mm Hg \(=\frac{1.013 \text { bar }}{760 \mathrm{~mm} \mathrm{Hg}} \times 740 \mathrm{~mm} \mathrm{Hg}\)

= 0.986 bar.

Liquids and Gases States of Matter Class 11 Chemistry Notes

Question 2. A bulb filled with a gas is connected to an open-end manometer. The level of mercury in the arm attached to the gas bulb is 20 cm lower than that in the open-ended arm. Calculate the pressure of the gas in the bulb in the units of atm and Pa. Consider the atmospheric pressure to be 76 cm Hg.
Answer:

Since the height of the mercury level in the open-end arm is higher than that in the arm attached to the bulb,

⇒ \(P_{\text {gas }}=P_{\text {atm }}+h=(76+20) \mathrm{cm} \mathrm{Hg}=96 \mathrm{~cm} \mathrm{Hg}\)

h = 20cm, p atm = 76cm hg]

As 1 atm = 76 cm Hg

= 1.013 × 10⁵ Pa

⇒ \(96 \mathrm{~cm} \mathrm{Hg}=\frac{1 \mathrm{~atm}}{76 \mathrm{~cm} \mathrm{Hg}} \times 96 \mathrm{~cm} \mathrm{Hg}=1.26 \mathrm{~atm}\)

Question 3. An open-end manometer was used to determine the pressure of a gas present in a container. It was found that the height of the mercury level in the arm attached to the gas-filled container was 4 cm higher than that in the open-end arm. If the atmospheric pressure was measured to be 76 cm Hg, then what would be the pressure of the gas inside the container in the atm unit
Answer:

As the height of the mercury level in the arm attached to the container is higher than that in the open-end arm

⇒ \(P_{\text {gas }}=P_{\text {atm }}-h\)

⇒ \(P_{\text {gas }}=P_{\text {atm }}-h=(76-4.0) \mathrm{cm} \mathrm{Hg}=72 \mathrm{~cm} \mathrm{Hg}\)

Thus, the pressure of gas Inside the container

⇒ \(=72 \mathrm{~cm} \mathrm{Hg}=\frac{72 \mathrm{~cm} \mathrm{Hg}}{76 \mathrm{~cm} \mathrm{Hg}} \times 1 \mathrm{~atm}=0.94 \mathrm{~atm}\)

Temperature of a gas

Temperature is a measure of the degree of hotness or coldness ofa the body. It is a property that determines the direction of heat flow from one body to another.

The temperature of a body is measured by an instrument known as a thermometer. Three types of temperature scales are generally used. These are the Celsius scale, Fahrenheit scale, and Kelvin scale.

Celsius scale:

On the Celsius scale, the normal freezing and the normal boiling temperatures of pure water are O’C and 100°C, respectively. On this scale, 0°C (lower fixed point) and ItMTC (upper fixed point) are used as reference points, and the space between these two temperatures is divided into 100 equal divisions. Each division corresponds to 1°C.

Fahrenheit scale:

On the Fahrenheit scale, the normal freezing and the normal boiling temperatures of pure water are 32°F and 212°F respectively.

On this scale, 32°F (lower fixed point) and 212°F (upper fixed point) are used as reference points, and the space between these two temperatures is divided into 180 equal divisions. Each division corresponds to 1°.

Kelvin or absolute scale:

On this scale, -273°C temperature is considered as zero point and is termed as absolute zero temperature. Hence, the Kelvin scale is also called the absolute scale of temperature.

Each division on this scale is called IK [Note the temperature unit is K, not °K. The conventional degree symbol (°) is not written] and is equal to each division on the Celsius scale (i.e. equal to 1°C). So, the zero point on the Kelvin scale is 273-degree units below the zero point on the Celsius scale [i.e., 0°C).

Hence, 0°C = 273K and 0 K = -273°C. According to the absolute scale, the value of temperature is called absolute temperature and is generally expressed by the letter, T.

Relation between Celsius and Kelvin scale:

Let, a particular temperature in the Celsius scale be t°C and in the Kelvin scale be 7K.

As 0°C = 273 K, so (0 + f)°C = (273 + 1)K or’l t°C = (273 + t)K

Therefore, if the temperature on the Celsius scale is t°C, then this temperature kelvin scale will be (273 + t)K.

Example: 25 °C = (273 + 25) = 298 K,

-40°C = (273-40) = 233K

• The SI unit oftemperatureiskelvin(K).
• The value of temperature on the Kelvin scale is always positive.
• The numerical values of the change in temperature in both Celsius and Kelvin scales are the same.

Gas laws

The gaseous state is the simplest state of matter. All gases irrespective of their chemical nature, obey some general laws called gas laws. These laws are related to four measurable properties viz., pressure (P), volume (V), temperature (I), and amount or number of moles (n) of a gas.

Boyle’s law:

Relation between volume & pressure Robert Boyle performed a series of experiments to know how the volume of a given mass of gas at a constant temperature is changed with the pressure. The results of his experiments led him to put forward a law which is known as Boyle’s law.

Boyle’s law: At constant temperature, the volume of a given mass of gas is inversely proportional to its pressure.

Mathematical expression of Boyle’s law:

Suppose, at a constant temperature, the pressure and volume ofa definite mass of gas are P and V, respectively. According to Boyle’slaw,

⇒ \(V \propto \frac{1}{p}\) [when mass and temperature are constant]

⇒ \(\text { or, } V=K \times \frac{1}{P} \quad \text { or, } P V=K\)

Pressure Of A Gas 

The equation is the mathematical expression of Boyle’s law. In this equation, If is a constant, whose value depends on the mass and temperature ofthe gas.

• Therefore, according to Boyle’s law, at a constant temperature, the product of pressure and volume of a given mass of gas is always constant.
• Let us consider, that at a particular temperature, the pressure and volume of a definite mass of gas are P1 and Vl, respectively.
• Keeping the temperature constant, if the volume of the gas is changed from V₁ to V₂ by changing the pressure from P₁ to P₂, then according to Boyle’s law, at the initial state, P1V1 = K, and at the final state, P₂V₂ = K.

Therefore, P₁V₁ = P₂V₂ or, P₁/P₂ = V₂/V₁

Explanation of Boyle’s law:

Suppose, the pressure and volume of a definite amount of gas at a particular temperature are P and V, respectively. Thus, according to Boyle’s law, at a constant temperature, if the pressure of the gas is doubled (2P), the volume of the gas will become half of its initial volume ( V/2), and if the pressure is increased by a factor of four, then the volume will become one-fourth of its initial value ( V/4).

On the other hand, at a constant temperature, the pressure of the gas is halved (P/2), and the volume of the gas will become twice its initial volume (2V). Similarly, if the pressure is decreased to one-fourth of its initial pressure (P/4) the volume will become four times its initial volume (4 V).

Graphical representations of Boyle’s law:

Applicability of Boyle’s law:

At normal temperature and pressure, H₂, N₂, and light inert gases obey this law with some degree of approximation but gases such as NH₃, CO₂, etc. do not obey this law. Most gases follow Boyle’s law only at very high temperatures or at relatively low pressures.

States of Matter and Gases Class 11 Chemistry Notes

Molecular Interpretation of Boyish Law:

The pressure of a gas is the result of collisions of gas molecules with the walls of the container.

• At constant temperature if the volume of a given mass of gas is reduced, the number of molecules per unit volume of the gas increases.
• This results in an enhanced frequency of collisions of molecules with the walls of the container.
• As a result, the pressure of the gas increases. Alternatively, the frequency of collisions with the walls decreases with the increasing volume of a given mass of gas at a constant temperature, resulting in a decrease in the pressure of the gas.

Corollary of Boyle’s law—Relation between pressure and density:

Suppose, a gas with a mass of m has a pressure, volume, and density of P, V, and d, respectively, at a constant temperature. According to Boyle’s law, PV = K (constant); when the mass and temperature of the gas are constant.

⇒ \(\text { Density }(d)=\frac{\text { mass }}{\text { volume }}=\frac{m}{V} \text { or, } V=\frac{m}{d}\)

Therefore, \(P \times \frac{m}{d}=K \text { or, } \frac{P}{d}=\frac{K}{m}\)

Since m is fixed and K is constant at a given temperature
for a fixed mass of a gas, so \(\left(\frac{K}{m}\right)\) is also a constant. Thus, \(\frac{P}{d}\)= Constant or \(P \propto d\)

Hence, at a constant temperature, the density of a gas is directly proportional to its pressure i.e., the density ofa gas increases with increasing pressure and decreases with decreasing pressure.

If at a constant temperature, the densities of gas at pressures P₁ and P₂ are d₁ and d₂, respectively, then according to equation [1], we obtain

p₁/p₂=d₁/d₂

Numerical Examples

Question 1. A balloon contains 1.2L of air at a particular temperature and 90 cm Hg pressure. What will be the volume of air if the pressure is reduced to 70 cm Hg while keeping the temperature constant?
Answer:

Given, P₁ = 90 cmHg, P₂= 70 cmHg, V₁= 1.2 L & V₂ = ?

From the relation, P₁V₁ – P₂V₂, We have

⇒ \(V_2=\frac{P_1 V_1}{P_2}=\frac{90 \mathrm{~cm} \mathrm{Hg} \times 1.2 \mathrm{~L}}{70 \mathrm{~cm} \mathrm{Hg}}=1.54 \mathrm{~L} .\)

Thus, the volume of air at 70 cm Hg is 1.54L

Question 2. The volume of a certain amount of gas containing an incompressible solid is 100 cc at 760 mm Hg and 80 cc at 1000 mm Hg. What is the volume of the solid?
Answer:

Suppose the volume of the solid Vcc

So, the volumes ofthe gas at 760 mm Hg and 1000mm Hg are (100- V)cc and (80- V)cc, respectively.

Using the relation, P₁= P₂V₂, we have

760(100- V) = 1000(80- V) or, V = 16.7 cc

Therefore, the volume of the solid is 16.7 cc

Charles’ law: Relation between volume and temperature

In 1787, French scientist Jacques Charles suggested a law describing the effect of temperature on the volume of a given amount of a gas at a fixed pressure. This law is known as Charles’ law.

At constant pressure, the volume of a given mass of gas is increased or decreased by 1/273 part of its volume at 0°C for every 1-degree rise or fall in temperature. The fraction, 1/273 is the coefficient of volume expansion. The exact value of this fraction is 1/273.15 per °C, but it is generally taken as 1/273. The value of the coefficient of volume i.e., 1/273 per °C is the same for all gases.

Mathematical Explanation:

Let at constant pressure the volumes of a given mass of gas are V₀, V₁, Vt, and vt at 0°C, 1°C, t°C and -t°C respectively. According to Charles’ Law, increase in volume for a 1°C rise in temperature

⇒ \(\frac {V_0}{273}\) and increase in volume for a t°C temperature rise

⇒  \(t \times \frac{V_0}{273}\). Therefore the volume of the gas at 1°C,

⇒ \(V_1=V_0+\frac{V_0}{273}=V_0 \times\left(1+\frac{1}{273}\right)\) and that at t°C \(V_t=V_0+\frac{t \times V_0}{273}=V_0 \times\left(1+\frac{t}{273}\right)\)

Similarly, decrease in volume for t°C fall in temperature \(=t \times \frac{V_0}{273}\)

Hence, the volume ofthe gas at t°C

⇒ \(V_t^{\prime}=V_0-\frac{t \times V_0}{273}=V_0 \times\left(1-\frac{t}{273}\right)\)

Celsius temperature vs volume of a given amount of gas at a fined pressure:

At a fixed pressure, the volume of a definite mass of a gas increases with the rise in temperature on the Celsius scale (t°C), but the variation of volume with Celsius temperature does not occur in direct proportion.

For example, at a fixed pressure if the temperature (on the Celsius scale) of a definite mass of a gas is doubled, its volume is not twice its initial volume.

Plotting the volume (V) of a definite mass of gas against Celsius temperatures (t°C) at different constant pressures gives a straight line for each constant pressure. Each of these lines does not pass through the origin, as indicated by the relation

⇒ \(V_t=V_0\left(1+\frac{t}{273}\right)\)

This means that the volume of the gas is not directly proportional to the Celsius temperature. If the straight lines are extrapolated backwards, then all these lines meet the temperature axis at -273°C.

Therefore, at constant pressure and at a temperature of -273°C, the volume of a gas becomes zero. Below this temperature, the volume of the gas becomes negative, which is absurd. Thus -273°C is the lowest possible temperature and is called absolute zero.

Definition of absolute zero and absolute temperature:

Absolute zero:

The lowest possible temperature at which the volume of any gas is zero.

The temperature -273°C is called absolute zero because at -273°C the volume of any gas would become zero and any temperature below this would correspond to a negative volume of gas.

In practice, absolute zero temperature can never be reached; however, a temperature very close to absolute zero can be attained.

Reason for using the term absolute in absolute zero:

The absolute zero of temperature is independent of the nature, amount, pressure, or volume ofthe gas and it is not possible to get any temperature below absolute zero. Hence, the term ‘absolute’ is used in absolute zero.

The volume of a gas does not become zero at -273-C because the gas becomes liquid or solid before attaining this temperature.

So, at this temperature, Charles’ law is not applicable. Moreover, a gas is a substance of definite mass, and any mass will always occupy some volume. So, even if a substance exists in a gaseous state at – 273 °C, it must have a certain volume.

Absolute temperature:

The temperature scale which has been set up by taking -273°C as zero point and each degree is equal in magnitude to the one degree in Celsius scale is termed as the absolute scale of temperature. The values of temperature obtained from this absolute scale are called absolute temperatures.

Relation between volume & absolute temperature of a gas:

At constant pressure if the volumes of a certain amount of gas at 0°C and t°C are V0 and V, respectively, then,

⇒ \(V=V_0\left(1+\frac{t}{273}\right)=V_0\left(\frac{t+273}{273}\right)=\frac{V_0}{273} \times T\)

The quantity V0/273 for a definite mass of a gas is constant. So, V∝T. Thus at constant pressure, the volume of a given mass of gas is directly proportional to its absolute temperature.

For a given mass of gas at constant pressure, if we measure the volumes (V) of the gas at different absolute temperatures (T) and then draw a graph by plotting V against T, a straight line passing through the origin is obtained. The nature of the line implies that the volume of a given mass of gas at constant pressure is related to absolute temperature in the form of an equation as V = constant x T.

This means that the volume of a definite amount of a gas is directly proportional to its absolute temperature at constant pressure.

Alternative form of Charles’ law:

At constant pressure, the volume of a given mass of gas is directly proportional to the absolute temperature ofthe gas.

Mathematical form:

If at constant pressure, the volume of a given mass of gas at absolute temperature T is V, then according to Charles’ law V∝T or v=kt

Where K is a constant whose value depends on the mass and pressure of the gas.

Corollary-1:

If at constant pressure, a certain amount of gas occupies the volumes V₁ and V₂ at temperatures T₁ and T₂, respectively, then according to Charles’ law V₁∝ T₁ and V₂ ∝ T₂.

Therefore, V₁/V₂ =T₁/T₂

Corollary-2:

If T₂ = T₁/2 then according to equation V₂ = V₁/2 and if T₂ = 27, then V₂ = 2V₁.

So, at constant pressure, if the absolute temperature ofa definite mass of gas is reduced by half, the volume of the gas will be halved, and if the absolute temperature is doubled, the volume will become double.

Graphical representation of Charles’ law:

Applicability of Charles’ law:

Only a few gases approximately follow Charles’ law at ordinary temperature and pressure. For foremost gases, this law is best followed at low pressures or at very high temperatures.

Molecular interpretation of Charles law:

The velocity of gas molecules depends upon temperature. If the temperature of a gas is increased, the average velocity as well as the average kinetic energy of gas molecules increases.

Consequently, molecules collide with the walls of the container more frequently with greater force. This would increase the pressure ofthe gas if the volume ofthe gas remains constant. If the pressure of the gas is kept constant during the increase of temperature, then the volume ofthe gas must increase.

Corollary of Charles law—relation between density and temperature:

Let at constant pressure and absolute temperature T, the volume and density of a definite amount (m) of gas are V and d, respectively.

Therefore, \(K T=\frac{m}{d} \text { or, } d=\left(\frac{m}{K}\right) \times \frac{1}{T}\)

Since m is constant and K is fixed for a given mass of gas at constant pressure \(\left(\frac{m}{K}\right)\) is also a constant. Therefore \(d \propto \frac{1}{T}\)

Thus, at constant pressure, the density of a definite amount of gas is inversely proportional to the absolute temperature of the gas. If the absolute temperature of a gas is increased, its density decreases and vice-versa.

If at constant pressure, the densities of a definite amount of gas at absolute temperatures T₁ and T₂ are dx and d₂ respectively, then,

⇒ \(d_1 \propto \frac{1}{T_1} \text { and } d_2 \propto \frac{1}{T_2}\)

Therefore,d₁/d₂ =t₂/t₁

Numerical Examples

Question 1. At constant pressure, the temperature of a definite amount of a gas is increased from 0°C to t°C. As a result, the volume of the gas is increased by a factor of three. Calculate the value of t.
Answer:

We know, V₁/V₂ = T₁/T₂

Given, T₁ = 273 K, T₂ = (273 + t)K and V₂ = 3V₁

Where V1 is the volume ofthe gas at 0°C

∴ \(\frac{V_1}{3 V_1}=\frac{273}{273+t} \text { or, } 273+t=819\)

∴ t= 546°C.

Question 2. A 16 sample of oxygen at 760 mm Hg pressure and 27°C is kept In a container of 12.30 L capacity. What will be the temperature of the gas If the entire gas is transferred to a container of 24.6 L capacity, keeping the pressure constant?
Answer:

In this process, the mass and pressure of the gas remain fixed.

Hence according to Charles’ law, V₁/V₂ = T₁/T₂

Given, Vx = 12.30 L, V₂ = 24.60 L,

T₁ = 273 + 27 = 300 K and T₂ = ?

∴ \(T_2=T_1 \times \frac{V_2}{V_1}=300 \times \frac{24.60}{12.30}=600 \mathrm{~K}\)

Therefore, the temperature of the gas in the container of 24.6L will be =(600- 273)°C = 327°C.

Question 3. When ice and sample water, of hydrogen, occupies is an immerse exact volume of mixture 69.37 cc at 1 atm. At the same pressure, if the gas is immersed in boiling benzene, then its volume expands to 89.71 cc. What is the boiling point of benzene?
Answer:

As the pressure and amount of the H₂ gas are fixed, according to Charles’ law, V₁/V₂ = T₁/T₂

Temperature of the mixture of ice and water = 0°C = 273 K.

Given, Vx = 69.37cc and V₂ = 89.71cc.

∴ \(T_2=T_1 \times \frac{V_2}{V_1}=273 \times \frac{89.71}{69.37}=353.05 \mathrm{~K}\)

∴ The boiling point of benzene = (353.05- 273)°C = 80.05 °C

CBSE Class 11 Chemistry Liquids and Gases Notes

Gay-Lussac’s law of pressure: Relation between the pressure and temperature of a gas

Gay-Lussac’s law of pressure:

At constant volume, the pressure of a given mass of gas is directly proportional to its absolute temperature.

Mathematical form of Gay-Lussac’s law:

Let us assume, the pressure of a certain amount of gas at constant volume is P at absolute temperature T. According to Gay-Lussac’s law, P∝T is when the volume and mass of the gas are fixed.

Therefore, P = KT ……………………..(1)

Where K is a constant whose value depends on the mass and volume of the gas.

Corollary:

At fixed volume, if die pressures of a certain amount of gas are P₁ and P₂ at absolute temperatures T₁ and T₂ respectively, then according to Gay-Lussac’s law.

P₁ = KT₁ and P₂ = KT,  ……………………..(2)

Therefore, p₁/p₂ = T₁/T₂ From this equation [2], the value of any of the four quantities can be calculated If the other three quantities are known.

Graphical representation of Gay-Luseac’s law of pressure:

Molecular Interpretation of Gay-Lusm’s Law:

With an increase in the temperature of a gas, the average velocity, as well as the average kinetic energy of the gas molecules, increases, thereby making the molecules strike the walls of the container more frequently with greater force.

As a result, the force applied on the walls per unit area by the gas molecules increases with an increase in temperature, leading to the pressure of the gas.

Numerical Examples

Question 1. An iron cylinder contains He gas at a pressure of 250 kPa at 300K. The cylinder can withstand a pressure of 1 x 106 Pa. The room in which the cylinder is placed catches fire. Predict whether the cylinder will blow up before it melts or not. [M.P. ofthe cylinder = 1800K]
Answer:

We know, P₁/P₂ = T₁/T₂.

Given, P₁ = 250 kPa = 25 x 104 Pa,

T₁ = 300 K,P₂ = 106 pa and T₂ = ?

⇒ \(T_2=\frac{P_2}{P_1} \times T_1=\frac{10^6}{25 \times 10^4} \times 300=1200 \mathrm{~K}\)

As the final temperature is less than the melting point of iron, the cylinder would explode, instead of melting.

Question 2. A cylinder of cooking gas can withstand a pressure of 14.9 atm. At 27°C, the pressure gauge of the cylinder records a pressure of 12 atm. Due to a sudden fire in the building, the temperature starts rising. At what temperature, will the cylinder explode?
Answer:

We know, \(\frac{P_1}{P_2}=\frac{T_1}{T_2} \text {, }\)

The cylinder can withstand a pressure of 14.9 atm If the pressure ofthe cylinder at T2K is 14.9 atm then \(T_2=\frac{P_2}{P_1} \times T_1=\frac{14.9}{12} \times 300=372.5 \mathrm{~K}\)

Since P₁ = 12 atm and T₁ = (273 + 27) = 300 K]

As the cylinder can withstand pressure upto 14.9 atm, it will explode at a pressure above 14.9 atm. The pressure of the cylinder becomes greater than 14.9 atm when the temperature is greater than 372.5 K or 99.5°C. Hence the cylinder will explode at a temperature greater than 99.5°C.

Avogadro’s law: Relation between the volume and amount (number of moles) of a gas.

Avogadro’s law:

At a constant temperature and pressure, the volume of a gas is directly proportional to the number of moles ofthe gas.

Explanation:

At constant temperature and pressure, if the volume of n mole of a gas is V, then according to Avogadro’s law, V∝n or, V = Kx n where K= proportionality constant. The value of K depends on temperature and pressure.

At constant temperature and pressure, if the volumes of nl and n2 moles of a gas are V1 and V2, respectively, then according to Avogadro’s law, V1ocn1 and V2 oc n2.

Therefore \(\frac{V_1}{V_2}=\frac{n_1}{n_2}\)

This equation tells us that at constant temperature and pressure, if the number of moles of a gas is halved, the volume of the gas will become half of its initial volume, and, the volume of the gas becomes twice its initial value when the number of moles of the gas is doubled.

Suppose, two gases A and B with the number of moles n₁ and n₂, respectively, have volumes V₁ and V₂, at a given temperature and pressure. If:

n₁ = n₂, then according to equation (1), V₁ V₂ i.e., at the same temperature and pressure equal volumes of two gases contain the same number of molecules. This deduction is commonly known as Avogadro’s hypothesis.

Graphical representation of Avogadro’s law:

Molecular interpretation of Avogadro’s law:

At constant temperature, increasing the number of moles of the gas does not alter the average kinetic energy of the gas molecules. But the frequency of collisions ofthe molecules with the walls of the container increases as the number of molecules of the gas increases. This would increase the pressure of the gas if the volume of the gas is held constant. If the pressure of the gas remains constant, then the volume of the gas must increase.

A combination of Boyle’s law and Charles’ law

Suppose, the pressure, temperature, and volume of a given mass of gas are P, T, and V respectively.

According to Boyle’s law \(V \propto \frac{1}{p}\) [at constant temperature and for a given mass of gas] According to

Charles’ law, Foe T [at constant pressure and for a given mass of gas] Combining these two relations gives a relation that shows the variation of the volume of a given mass of gas with pressure
and temperature. Doing the combination, we have

⇒ \(V \propto \frac{T}{P}\) ………………………..(1)

⇒ \(\text { or, } \boldsymbol{V}=\boldsymbol{K} \times \frac{\boldsymbol{T}}{\boldsymbol{P}} \quad \text { or, } \frac{\boldsymbol{P V}}{\boldsymbol{T}}=\boldsymbol{K} \text { or, } \boldsymbol{P V}=\boldsymbol{K} \boldsymbol{T}\)

Where K is a proportionality constant whose value depends on the amount of the gas. Equation [1] i.e. PV = KT is the combined form of Boyle’s law and Charles’ law.

This equation explains that the product of pressure and volume of a definite mass of gas is directly proportional to its absolute temperature. If P₁ V₁, and T₁ are the pressure, volume, and temperature, respectively, of a definite mass of gas at a certain state and P₂, V₂ and T₂ are the pressure, volume, and temperature, respectively, for the same gas at another state, then from equation [1], we get

⇒ \(\frac{P_1 V_1}{T_1}=K \text { and } \frac{P_2 V_2}{T_2}=K\)

therefore \(\frac{P_1 V_1}{T_1}=\frac{P_2 V_2}{T_2}\)

Using this ‘equation, we can calculate any one of the quantities if the values ofthe remaining are known ∴

Standard temperature and pressure (STP):

Since the properties of I gases change with a change in pressure and temperature, we must use a common reference state to compare the properties of different gases. For this reason, scientists have set a standard temperature and pressure for comparing the properties of gases.

The standard pressure is taken as 1 atm (or 76 cm Hg or 760 mm Hg) and the standard temperature is taken as 0°C. The conditions 0°C and 1 atm are called Standard Temperature and Pressure (STP).

Numerical Examples

Question 1. At a given temperature and pressure, the volume of 10 g of He gas is 61.6L. How much of He gas has to be taken out at the same temperature and pressure to reduce its volume to 25L?
Answer:

10 g He \(=\frac{10}{4}=2.5 \mathrm{~mol}\) Atomic mass of He = 4 molar mass of He (monatomic gas) = 4 g.mol^-1]

We know at constant temperature and pressure \(\frac{V_1}{V_2}=\frac{n_1}{n_2}\)

Given, V₁ = 61.6 L, V₂ = 25 L, n₁ = 2.5 and n₂=?

∴ \(n_2=n_1 \times \frac{V_2}{V_1}=2.5 \times \frac{25}{61.6}=1.015 \mathrm{~mol}\)

1.015 mol He = 4 × 1.015 = 4.06 g He

∴ The volume of the gas will be 25L if (10 – 4.06) = 5.94g of He gas is taken out

Gases and Liquids in States of Matter Class 11 Chemistry Notes

Question 2. At a particular temperature and pressure, the volume of 12 g of H₂ gas is 134.5 L. What will be the final volume of the gas if 4 g of H₂ gas is added to it at the same temperature and pressure?
Answer:

12g H₂ \(=\frac{12}{2}=6\) of H₂.

Similarly, 4 g H₂ = 2 mol of H₂.

We know, at constant temperature and pressure \(\frac{V_1}{V_2}=\frac{n_1}{n_2}\)

Given that, n₁ = 6, n₂ = 6 + 2 = 8, V1 = 134.5 L and V₂ = ?

∴ \(V_2=\frac{n_2}{n_1} \times V_1=\frac{8}{6} \times 134.5=179.3 \mathrm{~L}\)

Therefore, at the same temperature and pressure, if 4 g of H₂ gas is added to 12 g of H₂ gas, then the final volume of the gas will be 179.3 L.

Equation Of State For An Ideal Gas

Four variables, viz. pressure (P), volume (V), temperature (X) and number of moles (n) are generally found to be sufficient to describe the state ofa gas. The relation connecting P, V, and Tandn of a gas is called the equation of state of the gas.

The gas laws, i.e., Boyle’s law, Charles’ law and Avogadro’s law can be combined into an equation that describes the behaviour of an ideal gas. This relation is called the equation of state of an ideal gas.

Derivation of the equation of state of an ideal gas:

According to Boyle’s law, \(V \propto \frac{1}{P}\); [ T & n are constant]

According to Charles’ law, V∝T,[P &t n are constant]

According to Avogadro’s law, V∝ n [P & T are constant]

Combining these three relations, we have \(V \propto \frac{T \times n}{P}\) when P, T and n ofthe gas vary therefore \(V=K \times \frac{n T}{p}\)

K is the proportionality constant. It has been experimentally found that the value of K for 1 mol of any gas is the same.

For 1 mol of a gas, K is denoted by R, which is called the molar gas constant. As the value of R is the same for all gases, ‘JR’ is also called the universal gas constant.

Substituting R for equation [1], we obtain

⇒ \(V=R \times \frac{n T}{P}\) or, PV=nRT

Equation [2] expresses the equation of state for n mol of an ideal gas. In this equation, if the values of the three variables are known, the value ofthe fourth variable can be calculated by this equation.

For 1 mol of an ideal gas i.e., when n = 1, PV = RT— this expresses the equation of state for 1 mol of an ideal gas.

In equation PV = RT, P and V are the pressure and volume, respectively, of 1 mol of an ideal gas at temperature T.

In equation PV = nRT, P and V are the pressure and volume, respectively, of n mol of an ideal gas at temperature T.

The equation PV = NRT does not have any quantity related to the nature of the gas. Thus, this equation applies to an ideal gas.

Ideal gas:

A gas which obeys the equation of state, PV = nRT under all conditions is called an ideal gas. But in reality, there is no such gas which perfectly obeys the ideal gas equation under all conditions.

Therefore, the concept of ideal gas is a hypothetical one. However, it has been found experimentally that gases are nearly deadly at very low pressures and high temperatures.

Real gas:

Gases which do not obey the equation of state, PV = nRT in any condition except at very high temperatures and very low pressures are said to be real gases. All naturally occurring gases are real gases.

Significance of R and values of R in different units

Significance of molar gas constant (R):

For n mol of an ideal gas Pv=nRT or \(\frac{P V}{n T}\). The physical significance of R can be explained from its dimension.

Dimension of R. = \(\frac{\text { pressure } \times \text { volume }}{\text { number of moles } \times \text { temperature }}\)

We know, dimension of pressure = \(\frac{\text { force }}{(\text { length })^2}\)

On the other hand, the dimension ofvolume= (length)³ Temperature is expressed Kelvin scale. Dimension of R =

⇒ \(\frac{\frac{\text { force }}{(\text { length })^2} \times \text { length }^3}{\text { mole } \times K}=\frac{\text { work (or energy) }}{\text { mole } \times \mathrm{K}}\)

Hence, R= work (or energy) per kelvin per mole of gas Therefore, the value of R gives the measure of the work performed by 1 mol of an ideal gas when the temperature of the gas is raised by IK against a fixed pressure. This is the physical significance of R.

Values of R in different units:

We know \(R=\frac{P V}{n T}\) Therefore, the values and units of R depend upon the values and units of P, V, n and T. Temperature is always expressed in kelvin scale and n is expressed in the unit of mole.

Values of R in different units:

Determination of the values of R In different units:

Boltzmann constant:

Dividing the molar gas constant (R) by Avogadro’s number (A) gives a new constant, termed the Boltzmann constant (k). It indicates the universal gas constant for a single molecule.

Therefore, \(k=\frac{R}{N}=\frac{R}{6.022 \times 10^{23} \mathrm{~mol}^{-1}}\)

In CCSA System \(k=\frac{R}{N}=\frac{8.314 \times 10^7 \mathrm{erg} \cdot \mathrm{mol}^{-1} \cdot \mathrm{K}^{-1}}{6.022 \times 10^{23} \mathrm{~mol}^{-1}}\)

=1.38 × 10^-16 erg. K^-1

In SI, \(k=\frac{R}{N}=\frac{8.314 \mathrm{~J} \cdot \mathrm{mol}^{-1} \cdot \mathrm{K}^{-1}}{6.022 \times 10^{23} \mathrm{~mol}^{-1}}\)

= 1.38 × 10^-23J . K^-1

Application to the Ideal gas equation

Determination of density and molar mass of an ideal gas:

The equation of state for n mol of an ideal gas is PV = nRT, where V is the volume of nmol of the ideal gas at pressure P and temperature T. If m and M are the mass (in gram) and molar mass (in g.mol-1 ) of the gas, respectively, then the number of moles ofthe gas (n) is given by

⇒  \(\frac{m}{M}\)

Substituting \(\frac{m}{M}\) for n in the equation PV = nRT

We have \(P M=\left(\frac{m}{V}\right) R T\)

So, PM = dRT or, \(d=\frac{P M}{R T}\) ………………………….(1)

Equation [1] is the relationship among the density, pressure, absolute temperature and molar mass of an ideal gas. This equation can be used to calculate the molar mass (A) of an ideal gas if the density ofthe gas (d) at a given and T is known or the density of an ideal gas at a given P and T, if the molar mass ofthe gas is known.

Important points related to the equation, d = PM/RT:

1. The relation between the density and molar mass of an ideal gas at a particular temperature and pressure:

According to the equation, d = PM/RT, the density of an ideal gas at a particular temperature and pressure is directly proportional to its molar mass i.e., d∝M.

Therefore, at a given temperature and pressure a heavier gas has higher density than a lighter gas. The average molar mass of air is greater than the molar mass of He gas. So at a particular temperature and pressure, the density of He gas is less than that of air. This is why, a balloon filled with gas floats in the air.

2. The relationship of density with pressure and absolute temperature of a gas:

According to the equation,

⇒ \(d=\frac{P M}{R T}\)

The density of ideal gas is directly proportional to RT to its pressure and inversely proportional to its absolute temperature. Therefore, at a given temperature the density of a gas increases (or decreases) as the pressure of the gas increases (or decreases).

On the other hand, at a given pressure the increase in temperature of a gas results in the lowering of its density and the decrease in temperature increases its density. The density of hot air is less than that of cold air. This is why the balloon filled with hot air easily moves upward in the air.

3. The relation among pressure, temperature and density ofa gas at two different pressures and temperatures:

Let dx be the density of a gas at pressure P_x and temperature T₁ and d₂ be the density of the same gas at pressure P₂ and temperature T₂. Therefore, according to the equation,

⇒ \(d=\frac{P M}{R T}\)

The densities of the gas at two conditions are d1 =

⇒ \(d_1=\frac{P_1 M}{R T_1} \text { and } d_2=\frac{P_2 M}{R T_2}\)

Thus, \(\frac{d_1}{d_2}=\frac{P_1}{P_2} \times \frac{T_2}{T_1}\) ………………………….(2)

4. This equation expresses the relation between the densities of a gas at two different pressures and temperatures.

If the density of a gas at a particular temperature and pressure, is known, then the density of the gas at another temperature and pressure can be determined from equation [2].

Validity of ideal gas equation

The ideal gas equation is not exactly followed by any gas. However, it has been found that most gases approximately follow this equation when pressure is not too high or temperature is not too low.

Despite its limitations, the ideal gas equation is often used to determine the approximate values of the various properties of real gases under ordinary conditions. But for the estimation of the exact values of the properties, this equation can never be used.

Numerical Examples

Question 1. Find the volume of 2.2g CO₂ gas at 25°C & 570 mm Hg pressure. Consider that CO₂ behaves ideally.
Answer:

Given, \(P=\frac{570}{760}\) 0.75 atm; T= (273 + 25) = 298 K.

⇒ \(n=\frac{2.2}{44}=0.05 \mathrm{~mol}\)

Molar mass of CO₂ = 44g mol-1]

⇒ \(V=\frac{n R T}{P}\)

⇒ \(=\frac{(0.05 \mathrm{~mol}) \times\left(0.0821 \mathrm{~L} \cdot \mathrm{atm} \cdot \mathrm{mol}^{-1} \cdot \mathrm{K}^{-1}\right) \times 298 \mathrm{~K}}{0.75 \mathrm{~atm}}\)

=  \(1.63 \mathrm{~L}\)

Therefore, at 25°C and 570 mm Hg pressure, the volume of 2.2 g of CO₂ gas is 1.63 L.

Question 2. A sample of Ar vapour contains 3 x 104 atoms of a vacuum tube with a volume of 5 mL at -100°C. Calculate the pressure of the vapour in the microtorr unit.
Answer:

Given, V = 5 mL = 5 x 10-3 L; T = 273- 100 = 173 K

⇒ \(\text { and } n=\frac{\text { number of molecules }}{\text { Avogadro’s number }}\)

= \(\frac{3 \times 10^4}{6.022 \times 10^{23}}=4.98 \times 10^{-20} \mathrm{~mol}\)

Argon is monoatomic.

⇒ \(P=\frac{n R T}{V}\)

⇒ \(\frac{4.98 \times 10^{-20} \mathrm{~mol} \times 0.0821 \mathrm{~L} \cdot \mathrm{atm} \cdot \mathrm{mol}^{-1} \cdot \mathrm{K}^{-1} \times 173 \mathrm{~K}}{5 \times 10^{-3} \mathrm{~L}}\)

= 1.414 × 10^-16 atm

As, 1 atm = 760 torr,

P = ( 1.414 × 10^-16 × 760) = 1.074 × 10^-13 torr

= 1.074 × 10^-7 microtorr

Since 1 torr = 10⁶ microtorr

Therefore the pressure of argon vapour = 1.074 × 10^-7 micro torr

Question 3. At 273K and 76 pressure, the volume of 0.64 g of gas is 224 mL. At what temperature 1g of this gas will occupy a volume of 1 litre at atmospheric pressure?
Answer:

Given, P = 76 cm Hg = 1 atm, T = 273 K, V = 224 mL = 0.224 L

Number of moles (n) = \(\frac{0.64}{M} \mathrm{~mol}\)

[molar mass of the gas =M .g .mol^-1 ]

Putting the values of P, V, n and T into the equation PV = nRT gives

1 atm x 0.224L \(=\frac{0.64}{M} \times 0.0821 \mathrm{~L} \cdot \mathrm{atm} \cdot \mathrm{mol}^{-1} \cdot \mathrm{K}^{-1} \times 273 \mathrm{~K}\)

Substituting 8 P = 1 atm, V – 1 L,

n = \(\frac{1}{64.04} \mathrm{~mol}\) into equation PV – nRT, we obtain

⇒ \(T=\frac{P V}{n R}\)

= \(\frac{1 \mathrm{~atm} \times 1 \mathrm{~L}}{\frac{1}{64.04} \mathrm{~mol} \times 0.0821 \mathrm{~L} \cdot \mathrm{atm} \cdot \mathrm{mol}^{-1} \cdot \mathrm{K}^{-1}}\)

= \(780.02 \mathrm{~K}\)

Therefore, at (780.02-273) = 507.02°C and 1 atm pressure the volume of lg of gas will be 1 L.

Question 4. At 25°C and a certain pressure, 3.7g of a gas occupies the same volume as the volume occupied by 0.184g of H₂ gas at 17°C and the same pressure. Calculate the molar mass of the gas.
Answer:

For H₂ gas: T=(273 + 17) = 290K and \(n=\frac{0.184}{2}=0.092 \mathrm{~mol}\)

∴ PV= nRT=0.092 mol × 0.0821 L-atm-moH-K^-1 × 290K

=2.19 L atm

In case ofthe unknown gas: T = (273 + 25)K = 298 K;

⇒  \(n=\frac{3.7}{M} \mathrm{~mol}\)

∴ PV =nRT = \(=\frac{3.7}{M} \mathrm{~mol} \times 0.0821 \mathrm{~L} \cdot \mathrm{atm} \cdot \mathrm{mol}^{-1} \cdot \mathrm{K}^{-1} \times 298 \mathrm{~K}\)

= \(\left(\frac{90.52}{M}\right) \mathrm{L} \cdot \mathrm{atm}\)

Since the values of P and V are the same for both gases, the values of PV will also be the same for both gases

∴ \(\frac{90.52}{M}=2.19 \text { or, } M=41.33\)

Therefore, the molar mass of the other gas =41.33 g-mol^-1

Question 5. A He balloon is such that it can rise to a maximum height of 50 km above the Earth’s surface. When the balloon rises to this height, its expansion reaches a maximum with a volume of 105 L. If the temperature and pressure of the air at this height are 10 °C and 1.8 mm Hg, respectively, then what mass of He gas will be required for the maximum expansion of the balloon?
Answer:

Given, P = 1.8 mm Hg \(=\frac{1.8}{760}=2.368 \times 10^{-3} \mathrm{~atm} \text {; }\)

T = (273- 10)K = 263 K ; V = 105L and n = ?

∴ \(n=\frac{P V}{R T}=\frac{\left(2.368 \times 10^{-3} \mathrm{~atm}\right) \times\left(10^5 \mathrm{~L}\right)}{\left(0.0821 \mathrm{~L} \cdot \mathrm{atm} \cdot \mathrm{mol}^{-1} \cdot \mathrm{K}^{-1}\right) \times 263 \mathrm{~K}}\)

∴ 10.96 mol He = 10.96 × 4 = 43.84 g of He

since 1 mol of = 4 g He] 43.84 g of He will be required for the full expansion of the balloon.

Question 6. At 300K, an evacuated cylinder with a volume of 10L is filled with 2g of H₂ and 2g of D₂. Find the pressure of the gas mixture in the cylinder. Will the pressure be the same if the container is cubical having the same volume?
Answer:

2g H₂ \(=\frac{2}{2}\) H₂ and 2g D₂= \(=\frac{2}{4}\) 0.5 mol D₂

Since molar masses Of H₂ And D₂ Are 2 and 4 g. mol^-1 respectively]

No. of moles of H₂ & D₂ gas in the cylinder,

n = 1 + 0.5 = 1.5 mol

Given, T = 300 K and V = 10 L

Therefore, \(P=\frac{n R T}{V}=\frac{1.5 \times 0.0821 \times 300}{10}=3.69 \mathrm{~atm} .\)

Thus, the pressure ofthe mixture of H₂ and D₂ gas in the cylinder will be 3.69 atm.

For a given mass of gas at a fixed temperature, the pressure of the gas depends on the volume ofthe container but not on the shape ofthe container. Thus, the pressure will be the same if the container is cubical with the same capacity.

Question 7. When an open vessel at 27°C was heated, three-fifths of the air escaped from It. If the volume of (the lie vessel remained unchanged, calculate the temperature arc at which the vessel was healed.
Answer:

The amount of air present in the vessel at 27G was nmol, and when it was heated to 7’K \(\frac{3}{5}\) the air was expelled.

So, the amount of air in the vessel after heating

= \(\left(n-\frac{3 n}{5}\right)=\frac{2}{5} n \mathrm{~mol}\)

As the vessel was open and its volume remained unchanged on heating, the pressure (P) and the volume ( V) of the air presenting the vessel would be the same as those at 27°C.

At temperature 300 K: PV = nR × 300

At temperature 7K : \(P V=\frac{2}{5} n R T\)

Thus, no X 300 \(=\frac{2}{5} n R T\) or, T = 750 K

∴ The vessel was heated at (750- 273)°C = 477°C

Question 8. A spherical balloon with a diameter of 21 cm is to be filled with hydrogen gas at STP from a cylinder of H₂ gas at 20 atm pressure and 27°C. If the cylinder can hold 2.82 L of water, how many balloons can be filled with the hydrogen gas from the cylinder?
Answer:

Volume ofeach balloon \(=\frac{4}{3} \pi \times\left(\frac{21}{2}\right)^3=4851 \mathrm{~cm}^3=4.851 \mathrm{~L}\)

Since the cylinder can hold 2.82 L of water, the volume of the cylinder is 2.82 L and hence the volume of H₂ gas at 20 atm and 27°C is 2.82 L.

Let, volume of H₂ gasin the cylinder at STP = V₂ L.

We know, \(\frac{P_1 V_1}{T_1}=\frac{P_2 V_2}{T_2}\)

Given, P₁ = 20 atm; P₂ (STP) = 1 atm;

V₁ = 2.82 L; T₁ = (273 + 27)K = 300 K ;

T₂ (STP) = 273 K and V₂ = ?

∴ \(V_2=\frac{T_2}{T_1} \times \frac{P_1}{P_2} \times V_1\)

= \(\frac{273 \mathrm{~K}}{300 \mathrm{~K}} \times \frac{20 \mathrm{~atm}}{1 \mathrm{~atm}} \times 2.82 \mathrm{~L}\)

= \( 51.324 \mathrm{~L}\)

After the balloons are filled with H₂ gas, the cylinder will contain H₂ gas with a volume equal to its volume, l.e., 2.8.2 Hence, the volume of H₂ gas available for filling up the balloons will be = (51.324- 2.82)L =48.504 L Thus, no. of balloons that can be filled up.

⇒ \(\frac{48.504}{4.851}=10\)

Question 9. When 2 g of a gas ‘Af is introduced into an empty flask at 30°C, its pressure becomes 1 atm. If 3g of another gas ‘N’ is introduced in the same flask at the same temperature, the total pressure becomes 1.5 atm. Find the ratio of the molar masses of the two gases
Answer:

Let the molecular masses of gases, M and N be a and b gaol^-1 respectively and the volume ofthe flask = VL

In the case of gas Af:

P = 1 atm, T = (273 + 30)K = 303 K number of moles (n) \(=\frac{2}{a} \mathrm{~mol}\)

Therefore, according to the equation

PV = NRT \(1 \mathrm{~atm} \times V \mathrm{~L}\)

= \(\frac{2}{a} \mathrm{~mol} \times 0.0821 \mathrm{~L} \cdot \mathrm{atm} \cdot \mathrm{mol}^{-1} \cdot \mathrm{K}^{-1} \times 303 \mathrm{~K}\)

∴ \(V=\frac{49.75}{a} \mathrm{~L}\)

The number of moles of N gas \(=\frac{3}{b} \mathrm{~mol}\)

In case of the mixture of gases M and N: Total number of moles in the mixture of gases M and N \(\left(\frac{2}{a}+\frac{3}{b}\right)\) mol.

The total pressure of the mixture = 1.5 atm

By applying the equation, PV = not in the case of the mixture of gases, we obtain

⇒ \(1.5 \times \frac{49.75}{a}=\left(\frac{2}{a}+\frac{3}{b}\right) \times 0.0821 \times 303\)

or, \(\frac{74.62}{a}=\left(\frac{2}{a}+\frac{3}{b}\right) \times 24.87=\frac{49.75}{a}+\frac{74.62}{b}\)

or, \(\frac{24.87}{a}=\frac{74.62}{b}\)

∴ \(\frac{a}{b}=\frac{1}{3}\)

States of Matter: Liquids and Gases Class 11 Chemistry Notes

Question 10. What is nitric oxide’s density (in g-cm^-3) (assuming ideal behaviour) at 27 °C and 1 atm pressure?
Answer:

Given, P = 1 atm, T = (273 + 27)K = 300 K

Molar mass (M) of NO₂ = 30 g-mol^-1

∴ \(d=\frac{P M}{R T}=\frac{1^{\prime} \mathrm{atm} \times 30 \mathrm{~g} \cdot \mathrm{mol}^{-1}}{0.0821 \mathrm{~L} \cdot \mathrm{atm} \cdot \mathrm{mol}^{-1} \cdot \mathrm{K}^{-1} \times 300 \mathrm{~K}}\)

=1.218 g.L^-1

= 1.218 × 10^-3g.cm^-3

Question 11. The density of CO₂ at STP is 1.96 g-L1. A sample of CO₂ occupies a volume of 480mL at 17°C and 800mm Hg pressure. What is the mass of the sample?
Answer:

We know, \(\frac{d_1}{d_2}=\frac{P_1}{P_2} \times \frac{T_2}{T_1}\)

STP: d₁ = 1.96 g-L^-1, P₁ =1 atm, =273 K

At 17°C and 800 mm Pressure:

⇒ \(P_2=\frac{800}{760}=1.053 \mathrm{~atm} ; T_2=(273+17) \mathrm{K}=290 \mathrm{~K}, d_2=?\)

∴ \(d_2=d_1 \times \frac{P_2}{P_1} \times \frac{T_1}{T_2}=1.96 \times \frac{1.053}{1} \times \frac{273}{290}=1.94 \mathrm{~g} \cdot \mathrm{L}^{-1}\)

if the mass of 480 mL of CO₂ gas be w g, then \(d_2=\frac{w}{0.48} \mathrm{~g} \cdot \mathrm{L}^{-1}\)

∴ \(1.94 \mathrm{~g} \cdot \mathrm{L}^{-1}=\frac{w}{0.48} \mathrm{~g} \cdot \mathrm{L}^{-1}\)

∴ w= 09312g

Therefore, the mass of CO₂ gas is = 0.9312 g

Partial Pressure Of A Gas Dalton’s Law

Partial pressure

Let us consider that two non-reacting gases, A and B are kept in a closed vessel (i.e., of fixed volume) at a particular temperature. At this temperature, the mixture of gases (A and B) exerts a definite pressure on the vessel.

If gas B is completely removed from the gas mixture at the same temperature, then the pressure exerted on the vessel by gas A alone is known as the partial pressure of A.

Similarly, if gas A is completely removed from the gas mixture at the same temperature, then the pressure exerted on the vessel by B alone is known as the partial pressure of B.

Partial pressure Definition:

At a given temperature the pressure contributed by a component gas in a mixture of two or more non-reacting gases to the total pressure of the mixture is called the partial pressure of that component.

In 1807, John Dalton proposed a law regarding the partial pressures of two or more non-reacting gases, which is known as Dalton’s law of partial pressures.

Dalton’s law of partial pressures:

At constant temperature, the total pressure exerted by a mixture of two or more non-reacting gases present in a container of definite volume is equal to the sum of the partial pressures of component gases in the mixture.

If P is the total pressure of a gas mixture enclosed in a container of definite volume at constant temperature and p₁ p₂, p₃ etc., are the partial pressures of the component gases at the same temperature, then according to Dalton’s law of partial pressures, p=p₁+p₂+p₃………………….

This law does not work if the component gases react with each other. For example, in the case of a mixture of NH₃ and HC₁ gases, this law is not applicable because these two gases react to form NH₂Cl.

Explanation:

Suppose, two non-reacting gases A and B separately enclosed in two closed containers, each with a volume of V. Let us assume that the temperature of both gases is the same and the pressures of A and B gases are pA and pB, respectively.

If two gases, instead of enclosing separately, are mixed in another closed container with a volume of V, keeping the temperature constant, then the total pressure of the gas mixture will be (pA+pB).

Mathematical form of Dalton’s law of partial pressure

Suppose, a mixture of reacting gases 1, 2, 3.. with the number of moles n₁ n₂ n₃—, n- is enclosed in a closed container with a volume of V at a constant temperature T.

Also suppose, the partial pressure ofthe components 1, 2, 3,… i in the mixture are p₁ p₂,p₃—, , respectively.

If the component gases and the gas mixture obey the ideal gas law, then the total pressure ofthe gas mixture is.

⇒ \(P=\left(n_1+n_2+n_3+\cdots+n_i\right) \frac{R T}{V}\) …………………….(1)

Applying the ideal gas equation separately to each component gas ofthe mixture, we have,

⇒ \(p_1=\frac{n_1 R T}{V}, p_2=\frac{n_2 R T}{V}, p_3=\frac{n_3 R T}{V} \text { etc. }\)

So the total pressure ofthe gas mixture,

⇒ \(\left(p_1+p_2+p_3+\cdots+p_i\right)=\left(n_1+n_2+n_3+\cdots+n_i\right) \frac{R T}{V}\) …………………….(2)

Comparing equations (1) and (2) we obtain p = p₁+p₂+p₃+….+ pi

This is the mathematical expression of Dalton’s law of partial pressures.

The relation between the partial pressure and mole fraction

The mole fraction of a component in a gaseous mixture is the ratio of the number of moles of that component to the total number of moles of all components in the mixture. It is a unitless quantity with a value always less than one (1).

If a mixture of the number of moles of a component and the total number of moles of all the components be n. and n, respectively, then the mole fraction ofthe component,\(x_i=\frac{n_i}{n}\) The sum of the mole fractions of all the components in a mixture is always 1.

Relation between partial pressure and mole fraction:

Suppose, at constant temperature T, there is a mixture of some non-reacting gases in a container with a fixed volume of V and the pressure ofthe gas mixture is P.

If the number of moles of different component gases present in the mixture is n₁, n₂,n₃ …respectively, then the total number of moles of all components in the mixture, n = n₁ + n₂ + n₃ + If, the partial pressures of the component gases of the mixture are p₁ p₂, P₃………………etc., then according to Dalton’slaw of partial pressures, die total pressure of the gas mixture,

P = p₁ + p₂ + p₃+……………………(1)

Applying the ideal gas equation to the gas mixture gives PV = nRT

If this equation is applied to each component in the mixture, then

P₁V = n₁RT…………………………..(2)

P₂V = n₂RT…………………………..(3)

P₃V = n₃RT…………………………..(4)

Dividing equation (2) by equation (1) gives \(\frac{p_1}{P}=\frac{n_1}{n}=x_1\)

or, p₁ = x₁XP [xa = mole fraction ofthe component 1] Dividing equation [3] by equation [1] gives,

⇒ \(\frac{p_2}{P}=\frac{n_2}{n}=x_2 \text { or, } p_2=x_2 \times P\)

Similarly, for the ith component, if the partial pressure and mole fraction are pt and x; respectively, then

P_i=x_i × P…………………………..(5)

Where P is the total pressure of the gas mixture. Equation [5] represents the relation between the partial pressure and mole fraction of a component gas in a gas mixture at a constant temperature. So, the partial pressure of a component in a gas mixture = mole-fraction of the component x total pressure of the mixture.

Determination of partial pressure

Suppose, at a given temperature T, a bulb with a fixed volume of V_A contains nA moles of an ideal gas with a pressure P_A, and another bulb with a fixed volume of VB contains nB moles of another ideal gas with a pressure PB. These two flasks are connected by a stop-cock of negligible volume. Initially, the stop-cock is closed, so all molecules of gas A are in one bulb and that of gas B are in another bulb.

On opening the stop-cock, the two gases will mix, and the total volume ofthe gas mixture becomes (V_A + V_B). Let the partial pressures of A and B in the gas mixture be pA and pB, respectively, and the total pressure ofthe mix.

Before opening stop-cock: In case of gas A:

PAVA = nART

In case of gas B: PBVB = nBRT

After opening stop-cock:

In case of gas A: P_A(V_A V_B) = n_ARP

In case of gas B: P_B(V_A+ V_B) = n_BRPT

Note that PA PA because the volumes of gas A before and after the opening of stop-cock are VA and VA + VB respectively. For the same reason, PB≠ PB

In case of gas A: P_AV_A = P_A(V_A+ V_B). Thus,

⇒ \(p_A=\frac{P_A V_A}{V_A+V_B}p_A=\frac{P_A V_A}{V_A+V_B}\) ………………………..(1)

In case ofgas B: P_BV_B = P_B(V_A+ V_B) and

⇒ \(p_B=\frac{P_B V_B}{V_A+V_B}\) ………………………..(2)

Equations (1) and (2) express the partial pressures of gas A and B, respectively, in the gas mixture. According to Dalton’s law of partial pressures, the total pressure ofthe gas mixture,

⇒ \(\boldsymbol{P}=p_A+p_B=\frac{P_A V_A}{V_A+V_B}+\frac{P_B V_B}{V_A+V_B} \text { or, } \quad \boldsymbol{P}=\frac{\boldsymbol{P}_A V_A+P_B V_B}{V_A+V_B}\)

If the volume of two bulbs is the same, i.e., VA = 1/B, then the total pressure of the gas mixture,

⇒ \(P=\frac{\left(P_A+P_B\right) V_A}{2 V_A}=\frac{1}{2}\left(P_A+P_B\right)\)

Application of Dalton’s law of partial pressures (Determination of actual pressure of a gas collected by the downward displacement of water):

During the laboratory preparation, gases lighter than air and insoluble in water are usually collected in gas jars by downward displacement of water.

So, the gas becomes saturated with water vapour. Thus, the observed pressure (P) of the collected gas is the pressure ofthe moist gas.

The pressure of the moist gas (P) = pressure of the dry gas (Pg) + saturated vapour pressure of water (Pw) at laboratory temperature. Therefore p_g=P-P_W

The saturated vapour pressure of water (Pw) at laboratory temperature is known from Regnault’s table. So from equation (1), the pressure of the dry gas can easily be calculated.

The vapour pressure of water, present in the gas collected in a gas jar is called aqueous tension.

Validity of Oalton’s law of partial pressure:

Under ordinary conditions, real gases do not obey Dalton’s law of partial pressure. But they approximately obey Dalton’s law at very low pressures and high temperatures as intermolecular attractive forces become negligible at this condition.

Molecular Interpretation of Dalton’s law of partial pressures:

In an ideal gas, molecules do not feel any forces of attraction or repulsion. So in a mixture of non-reacting ideal gases, molecules behave Independently of one another and the pressure exerted by a component gas is not influenced by the presence of other gases.

So, at constant temperature and volume, the pressure exerted by a mixture of two or more non-reacting ideal gases is equal to the sum of the partial pressures of the component gases.

The partial volume of a gas in a mixture of non-reading gases—Amagato law:

According to this law, at constant temperature and pressure, the total volume of a mixture of two or more non-reacting gases is equal to the sum of partial volumes of component gases in the mixture.

If V is the total volume of a gas mixture at constant temperature and pressure, and v₁, v₂, v₃…..etc., are the partial volumes ofthe component gases ofthe mixture at the same temperature and pressure, then according to Amagat’s law of partial volumes V = v₁ + v₂ + v₃ +…

At constant temperature and pressure, if v-t and xt are the partial volume and mole fraction of the f-th component respectively and V is the total volume of the gas mixture, then it can be shown that v_i= x_i × v

Therefore, at constant temperature and pressure, the partial volume of a component gas in a gas mixture = mole fraction of that component x total volume of the mixture.

Numerical Example

Question 1. At 27°C, a cylinder of volume 10 L contains a gas mixture consisting of 0.4 g He, 1.6 g O₂ & 1.4 g H₂. Determine the total pressure of the mixture and the partial pressure of He in the mixture.
Answer:

Total number of moles of He, O₂ and N₂ gas in the mixture \((n)=\frac{0.4}{4}+\frac{1.6}{32}+\frac{1.4}{28}\) 0.1 + 0.05 + 0.05 = 0.2 mol.

[Molar masses of He, O₂ and N₂ are 4, 32 and 28gmol-1 respectively)

Given, V = 10 L, T = (273 + 27)K= 300 K

We know, PV= nRTor, P \(=\frac{n R T}{V}\)

∴ \(\mathrm{p}_{=}=\frac{0.2 \mathrm{~mol} \times 0.0821 \mathrm{~L} \cdot \mathrm{atm} \cdot \mathrm{mol}^{-1} \cdot \mathrm{K}^{-1} \times 300 \mathrm{~K}}{10 \mathrm{~L}}=0.4926 \mathrm{~atm}\)

∴ Total pressure ofthe gas mixture = 0.4926 atm

Number of moles of He gas =0.1 and its mole fraction \(=\frac{0.1}{0.2}=0.5\)

∴ The partial pressure of He gas in mixture = mole-fraction of He in the mixture × total pressure of the mixture = 0.5 × 0.4926

= 0.2463 atm

Question 2. The volume percentages of N₂, O₂ and He in a gas mixture arc were 25, 35 and 40, respectively. At a given temperature, the pressure of the mixture is 760 mm Hg. Calculate the partial pressure of each gas at the same temperature.
Answer:

According to Amagat’s law, at constant temperature and pressure, the partial volume of a component gas in a gas mixture = mole-fraction of that component x total volume of the mixture.

Therefore, in the given mixture, \(x_{\mathrm{N}_2}=\frac{25}{100}=0.25\)

⇒ \(x_{\mathrm{O}_2}=\frac{35}{100}=0.35 \text { and } x_{\mathrm{He}}=\frac{40}{100}=0.40\)

∴ In the mixture,

Partial pressure of N₂ = xN₂  ×P =0.25 × 760 =190 mm Hg

Partial pressure of O₂ =xO₂ × P= 0.35 × 760 = 266 mm Hg and

Partial pressure of He = x_He × P= 0.40 × 760 = 304 mm Hg

Question 3. A mixture of N₂ and O₂ at 1 bar pressure contains 80% N₂ by weight. Calculate the partial pressure of N₂ in the mixture.
Answer:

As 80 g N₂ is present in 100 g of mixture, the amount of O₂ in the mixture is 20 g.

Therefore, the number of moles of N₂ in the mixture

⇒ \(\left(n_{N_2}\right) \frac{80}{28}=2.857 \mathrm{~mol}\)

And the number of moles of O₂ in the mixture

⇒  \(\left(\mathrm{n}_{\mathrm{O}_2}\right)=\frac{20}{32}=0.625 \mathrm{~mol} .\)

∴ Total moles of the mixture (total)= nN₂ + NO₂ = 2.857 + 0.625

= 3.482mol

∴ Mole fraction of N₂ gas (xN₂)

⇒ \(\frac{n_1}{n}=\frac{2.857}{3.482}=0.82\)

And that of O₂ gas (xO₂) \(=\frac{n_2}{n}=\frac{0.625}{3.482}=0.18\)

In the mixture, the partial pressure of N₂ gas =rN₂

Total pressure of the mixture, = 0.82 ×1 bar

= 0.82 bar and that of O₂ gas = xO₂ ×  total pressure of the mixture

= 0.18× 1 bar

= 0.18 bar.

NCERT Solutions Class 11 Chemistry Liquids and Gases

Question 4. At a given temperature, the pressure in an oxygen cylinder is 10.3 atm. At the same temperature, the pressure in another oxygen cylinder of volume 1/3 rd of the first cylinder is 1.1 atm. Keeping temperature constant, if the two cylinders are connected, then what will be the pressure of O₂ gas in the system?
Answer:

Suppose the volume of the first cylinder = VL.

So, the volume of another cylinder \(\frac{V}{3} L.\)

In the case of the first cylinder: If the number of moles of O₂ gas

be n₁, then according to the equation PV = nRT

10.3 atm × VL = n₁ × 0.0821 L.atm. moH^-1. K^-1 ×  TK

∴ \(n_1=\frac{125.45 \times V}{T} \mathrm{~mol} .\)

In the case of the second cylinder: If the number of moles of O₂ gas is n₂, then according to the equation PV = nRT

⇒ \(1.1 \mathrm{~atm} \times \frac{V}{3} \mathrm{~L}=n_2 \times 0.0821 \mathrm{~L} \cdot \mathrm{atm} \cdot \mathrm{mol}^{-1} \cdot \mathrm{K}^{-1} \times T \mathrm{~K}\)

∴ \(n_2=\frac{4.46}{T} \times V \mathrm{~mol}\)

If two cylinders are connected, then die total volume of the system

⇒ \(=\left(V+\frac{V}{3}\right) \mathrm{L}=\frac{4}{3} V \mathrm{~L}\)

And the total number of moles of O₂ gas = n₁ + n₂

Applying equation PV = nRT, we obtain

⇒ \(P \times \frac{4}{3} V \mathrm{~L}=\left(n_1+n_2\right) \mathrm{RT}=\left(\frac{125.45 \times \mathrm{V}}{T}+\frac{4.46 \times \mathrm{V}}{T}\right) \times 0.0821 \times \mathrm{T}\)

or, P= \(\frac{3}{4} \times \frac{(125.45+4.46)}{T} \times 0.0821 \times T\)

= \(\frac{3}{4} \times 129.91 \times 0.0821\mathrm{~atm}=7.99 \mathrm{~atm}\)

∴ The pressure of the O₂ gas in the system will be 7.99 atm.

Question 5. Thermal decomposition of x g of KClO₃ produces 760 mL O₂, which is collected over water at 27°C and 714 mm Hg pressure. Find the value of x. [Given that at 27°C, aqueous tension = 26 mm Hg and atomic weights of K = 39, Cl = 35.5, 0=16
Answer:

Actual pressure of O2 collected over water = atmospheric pressure- aqueous tension

⇒ \(=(714-26)=688 \mathrm{~mm} \mathrm{Hg}=\frac{688}{760}=0.9052 \mathrm{~atm}\)

According to the given conditions volume of O₂ = 760 mL = 0.76 L and T = (273 + 27)K = 300 K If the number of moles of O₂ gas is n then,

⇒ \(n=\frac{P V}{R T}\)

= \(\frac{0.9052 \mathrm{~atm} \times 0.76 \mathrm{~L}}{0.0821 \mathrm{~L} \cdot \mathrm{atm} \cdot \mathrm{mol}^{-1} \cdot \mathrm{K}^{-1} \times 300 \mathrm{~K}}\)

= \(0.028 \mathrm{~mol}.\)

The equation for the thermal decomposition of KClO₃ is

⇒  \(2 \mathrm{KClO}_3(s) \rightarrow 2 \mathrm{KCl}(s)+3 \mathrm{O}_2(g)\)

Therefore, 3 mol O2(g) = 2 mol KClO₃ = 2 × 12250 g

=245g KCIO₃

∴ \(0.028 \mathrm{~mol} \mathrm{O}_2(\mathrm{~g}) \equiv \frac{245}{3} \times 0.028 \mathrm{~g}=2.286 \mathrm{~g} \mathrm{KClO}_3\)

∴ x = 2.286 g

Diffusion And Effusion Of A Gas

Diffusion of a gas:

Due to rapid and random molecular motions and large average intermolecular distance, when two or more non-reacting gases come in contact with each other, they spontaneously mix to form a homogeneous mixture.

For instance, when a bottle of perfume is opened at one corner of a room, a person at the other end of the room smells the pleasant odour of the perfume after some time.

Similarly, when a bottle containing a concentrated solution of ammonia is opened at one end of a laboratory desk, a person at the other end of the desk smells the odour of ammonia. This is because the molecules of the perfume or ammonia Intermix with air rapidly and spread. Such a phenomenon of spontaneous Inlet mixing of gases In called diffusion.

Diffusion of a gas Definition:

The process by which two or more non-reacting gases without any external help Intermix with one another spontaneously, Irrespective of their densities or molar masses to form a homogeneous gas mixture Is termed as diffusion.

Efusion of a gas:

Like diffusion, a process involving the flow of gas molecules IN effusion. If a container holding some gas is kepi In a vacuum and a tiny hole (or pinhole) is made in the container, the enclosed gas flows through the tiny hole Into the vacuum.

This process is called effusion, Effusion Is also found to occur when the pressure of a gas enclosed In a porous container (like a rubber balloon) is higher than that of the outside pressure. Due to higher pressure Inside the container, gas flows out through the pores of the container.

Efusion of a gas Definition:

The process by which a gas escapes its container through a tiny hole (or pinhole) into a vacuum or a region of lower pressure Is called an effusion.

Graham’s law of diffusion or effusion Law of diffusion:

At constant temperature and pressure, the rate of diffusion of a gas is inversely proportional to the square root of the density of the gas.

This law applies to an effusion process also. For an effusion process, according to Graham’s law, the rate of effusion of a gas at constant temperature and pressure is inversely proportional to the square root of its density.

Mathematical form:

If at a particular temperature and pressure, the rate of diffusion (or effusion) of a gas =r and the density of that gas = d, then according to Graham’s law

⇒ \(r \in \frac{1}{\sqrt{d}} \text { or, } r=\frac{K}{\sqrt{d}}\) [k= proportionality constant]………………. (1)

Equation (1) is the mathematical form of Graham’s law. If under the same conditions of temperature and pressure, the rates of diffusion (or effusion) of two gases A and B be r A and B respectively, then according to Graham’s law,

⇒ \(r_A \propto \frac{1}{\sqrt{d_A}} \text { and } r_B \propto \frac{1}{\sqrt{d_B}}\)

∴ \(\frac{r_A}{r_B}=\sqrt{\frac{d_B}{d_A}}\) ……………… (2)

d_A and d_B are the densities of A and B respectively. Relation between the rate of diffusion (or effusion) and the vapour density of a gas:

At a particular temperature, the density (d) of a gas is proportional to its vapour density (D); i.e., d oc D Therefore, equation (2) can be expressed as

⇒ \(\frac{r_A}{r_B}=\sqrt{\frac{d_B}{d_A}}=\sqrt{\frac{D_B}{D_A}} \text { or, } \frac{r_A}{r_B}=\sqrt{\frac{D_B}{D_A}}\) ……………… (3)

D_A and D_B are the vapour densities of A and B, respectively.

Hence, at constant temperature and pressure, the rate of diffusion (or effusion) of a gas is inversely proportional to the square root of its vapour density.

Relation between the rate of diffusion or effusion and the molar mass of a gas:

Vapour density \((D)=\frac{\text { molar mass }(M)}{2}\)

⇒ \(\frac{r_A}{r_B}=\sqrt{\frac{D_B}{D_A}}=\sqrt{\frac{M_B / 2}{M_A / 2}}=\sqrt{\frac{M_B}{M_A}} \text { or, } \frac{r_A}{r_B}=\sqrt{\frac{M_B}{M_A}}\)……………… (4)

M_A and M_B are the molar masses of A and B, respectively. Therefore, at constant temperature and pressure, the rate of diffusion (or effusion) of a gas is inversely proportional to the square root of its molar mass.

Relation between the volume of a gas effused and its molar mass:

At a constant temperature and pressure, if the V_A volume of gas A and V_B volume of gas B effused through the same porous wall in the same time t, then—

⇒ \(r_A=\frac{V_A}{t} \text { and } r_B=\frac{V_B}{t}\)

∴ \(\frac{r_A}{r_B}=\frac{V_A / t}{V_B / t}=\frac{V_A}{V_B}\)

Substituting this value into equation [4], we obtain

⇒ \(\frac{V_A}{V_B}=\sqrt{\frac{M_B}{M_A}}\)……………… (5)

Thus, under the identical set of conditions, the effused quantities of the two gases have volumes that are inversely proportional to the square roots of their molar masses.

Relation between the time taken for effusion and the molar mass:

Suppose, at constant temperature and pressure, two gases A and B are effusing through a porous wall. If tA and tB are the times required for effusion ofthe same volume ( V) of gases A and B, respectively, then

⇒ \(r_A=\frac{V}{t_A} \text { and } r_B=\frac{V}{t_B}\)

According to Graham’s law of effusion,

⇒ \(\frac{r_A}{r_B}=\sqrt{\frac{M_B}{M_A}} \text { or, } \frac{V / t_A}{V / t_B}=\sqrt{\frac{M_B}{M_A}} \text { or, } \frac{t_B}{t_A}=\sqrt{\frac{M_B}{M_A}} \text { or, } \frac{t_A}{t_B}=\sqrt{\frac{M_A}{M_B}} \cdots[6]\) ……………… (6)

Therefore, under the same conditions of temperature and pressure, the times required for the effusion of the same volume of two gases through a porous wall are directly proportional to the square roots of their molar masses.

At a particular temperature, the rate of diffusion or effusion (r) of any gas is proportional to the pressure (P) of the gas and inversely proportional to the square root of the molar mass (Af) of the gas.

Therefore, If at a constant temperature, two gases A and B diffuse (or effuse) at pressures PA and PB, respectively, and their molar masses are M_A and M_B, then

⇒ \(r_A \propto P_A / \sqrt{M_A} \text { and } r_B \propto P_B / \sqrt{M_B}\)

Where rA and rB are the rates of diffusion (or effusion) of gases A and B, respectively therefore

⇒  \(\frac{r_A}{r_B}=\frac{P_A}{P_B} \sqrt{\frac{M_B}{M_A}}\)

Applications of diffusion (effusion) of gases:

Determination of the molar mass of a gas:

Under identical conditions of temperature and pressure, if equal volumes of two gases, A and B pass through a porous wall in times tA and tB, respectively, then according to Graham’s law

⇒ \(\frac{t_A}{t_B}=\sqrt{\frac{M_A}{M_B}} \text { or, }\left(\frac{t_A}{t_B}\right)^2=\frac{M_A}{M_B}\)

[M_A and M_B are the molar masses of A and B respectively]

If the time taken for the diffusion of the same volume of two gases under the same conditions of temperature and pressure and the molar mass of one of the gases is known, then from equation [1], the molar mass of the other gas can be calculated.

Separation of the component gases from the mixture of two gases:

At constant temperature and pressure, the rate of diffusion or effusion of any gas is inversely proportional to the square root of its molar mass. So, if a mixture of two gases is allowed to pass out through a porous wall, then the quantity ofthe gas diffused out after a definite interval will be enriched by the lighter gas.

In the same manner, two gases can be entirely separated by repeated diffusion or effusion through a porous wall. Such a process of separation of the components of a gaseous mixture based on the diffusive properties of gases is called atmolysis.

Example:

Two common isotopes of hydrogen gas, protium (JH) and deuterium (ÿH)can be easily separated by this method. But in most cases, the separation of isotopes is not easier by this method because ofthe very small ratio of the atomic masses of these isotopes.

Detection of marsh gas in coal mines:

To indicate the presence of marsh gas in coal mines, an electric alarm is used, which works on the principle of diffusion.

An experiment of gaseous diffusion

Diffusion of gases can be understood from the following experiment. A cotton plug soaked in concentrated HC₁ solution is inserted into one end of a long tube, and another cotton plug soaked in concentrated NH₃ solution is inserted into the other end ofthe tube.

The two ends ofthe tube are then closed with rubber corks so that HC₁ and NH₃, After some time, a white fume first appears at a point P inside the tube. It is the vapour of NH₄ Cl formed by the reaction between NH₃ and HCl vapours.

Point P lies near the cotton ball soaked in HC₁ solution than that soaked in NH₃ solution. This is because the diffusion rate of the lighter NH₃ gas is greater than that of the heavier HCl gas and hence NH₃ molecules travel a longer distance than HCl molecules in a given time.

Numerical Examples

Question 1. The rate of diffusion of a gas is 2.92 times that of NH₃ gas. Determine the molecular weight of that gas.
Answer:

If the rates of diffusion of the unknown gas and NH₃ gas at constant temperature and pressure are rx and r2, then according to Graham’s law of diffusion

⇒ \(\frac{r_1}{r_2}=\sqrt{\frac{M_{\mathrm{NH}_3}}{M}}\)

gas and MNH₃ = 17

Since, rx = 2.92 × r²

∴ \(2.92=\sqrt{\frac{17}{M}} \quad \text { or, } M=2\)

Therefore, the molecular weight ofthe unknown gas = 2

Question 2. 432 mL of gas A effuses out through a fine orifice in 36 min. 288 mL of another gas B effuses out through the same orifice in 48 min. If the molecular weight of B is 64, what is the molecular weight of A?
Answer:

According to Graham’s law of effusion \(\frac{r_A}{r_B}=\sqrt{\frac{M_B}{M_A}}\)

Given \(r_A=\frac{432 \mathrm{~mL}}{36 \mathrm{~min}}=12 \mathrm{~mL} \cdot \mathrm{min}^{-1},\)

⇒ \(r_B=\frac{288 \mathrm{~mL}}{48 \mathrm{~min}}=6 \cdot \mathrm{mL} \cdot \mathrm{min}^{-1} \text { and } M_B=64\)

∴ \(\frac{12}{6}=\sqrt{\frac{M_B}{M_A}}\)

∴ \(M_B=4 \times M_A \text { or, } M_A=\frac{64}{4}=16\)

Question 3. The molecular weights of the two gases are 64 and 100 respectively. If the rate of diffusion of the first gas is 15 mL.sec^-1, then what is the rate of diffusion of the other?
Answer:

According to Graham’slaw ofdiffusion \(\frac{r_A}{r_B}=\sqrt{\frac{M_B}{M_A}}\)

Here, M_A = 64, M_B = 100, r_A = 15 mL.s^-1 r_AB = ?

∴ \(\frac{15 \mathrm{~mL} \cdot \mathrm{s}^{-1}}{r_B}=\sqrt{\frac{100}{64}}=\frac{10}{8}\)

∴ rB = 12 mL-s^-1

∴ The rate of diffusion ofthe other gas = 12 mL.s^-1

Question 4. Determine the relative rates of diffusion of ^₂₃₅UF₆   And ^₂₃₈UF₆  UF6 Gases.
Answer:

Molecular weight of ^₂₃₅UF₆  =235 + 6 × 19 = 349

And molecular weight of _²³⁸ UF₆  = _²³⁸ UF₆

= 238+6 × 19

= 352

At a given temperature and pressure if r₁ and r₂ are the rates of diffusion of and ^₂₃₈UF₆  respectively,

Then according to Graham’s law,

⇒ \(\frac{r_1}{r_2}=\sqrt{\ \frac {M_2}{M_1}}=\sqrt{\frac{352}{349}}=1.0043\)

∴ r1=1.0043 × r²

∴ The rate of diffusion of ^₂₃₅UF₆  is 1.0043 times that of ^₂₃₈UF₆

Question 5. In a mixture of O₂ and an unknown gas, the percentage of the unknown gas Is 20% by mass. At a given temperature and pressure, the time required to effuse VmL of the gas mixture through an aperture is 234.1 s. Under the same conditions, the time required to effuse the same volume of pure 02 gas is 223.1 s. What is the molar mass of unknown gas?
Answer:

Average molecular mass of the gas mixture

⇒ \(\frac{20 \times M+80 \times 32}{100}\)

Where,

M = molar mass of unknown gas. According to the problem, the rate of effusion of VmL of unknown gas mixed with oxygen,

⇒  \(r_1=\frac{V}{234.1} \mathrm{~mL} \cdot \mathrm{s}^{-1}\)

And the rate of effusion of 7raL of pure oxygen

⇒  \(r_2=\frac{V}{223.1} \mathrm{~mL} \cdot \mathrm{s}^{-1}\)

We know, ,\(\frac{r_1}{r_2}=\sqrt{\frac{M_2}{M_1}}\) and \(\frac{r_1}{r_2}=\sqrt{\frac{M_2}{M_1}}\)

Now, \(\frac{M_2}{M_1}=\frac{32}{\frac{20 M+2560}{100}}=\frac{160}{M+128}\)

∴ \(\frac{223.1}{234.1}=\sqrt{\frac{M_2}{M_1}}=\sqrt{\frac{160}{M+128}} \quad \text { or, } 0.9082=\frac{160}{M+128}\)

∴ M= 48.17

The molar mass of unknown gas = 48.17gmol^-1

Question 6. A gas mixture consisting of He and CH₄ gases in a mole ratio of 4:1 is present in a vessel at a pressure of 20 bar. Due to a fine hole in the vessel, the gas mixture undergoes effusion. What is the composition (or ratio) of the initial gas mixture that is effused out?
Answer:

If the total number of moles in the mixture is n, then the numbers of moles of He and CH4 are \(\frac{4}{5} n \text { and } \frac{1}{5} n\) or, 0.8n and 0.2 n respectively.

In the mixture, the partial pressure of He (pHe)

⇒ \(=\frac{0.8 n}{n} \times 20=16 \text { bar and that of } \mathrm{CH}_4\left(p_{\mathrm{CH}_4}\right)\)

⇒ \(=\frac{0.2}{n} \times 20=4 \text { bar }\)

Rate of effusion of a gas at a constant temperature, \(r \propto \frac{P}{\sqrt{M}}\)

where P = pressure ofthe gas and M molar mass ofthe gas.

Therefore, the rate of effusion of He gas, \(r_1 \propto \frac{p_{\mathrm{He}}}{\sqrt{M_{\mathrm{He}}}}\)

⇒ \(\text { or, } r_1 \propto \frac{p_{\mathrm{He}}}{\sqrt{4}} \text { and that of } \mathrm{CH}_4 \text { gas, } r_2 \propto \frac{p_{\mathrm{CH}_4}}{\sqrt{M_{\mathrm{CH}_4}}} \text { or, } r_2 \propto \frac{p_{\mathrm{CH}_4}}{\sqrt{16}}\)

∴ \(\frac{r_1}{r_2}=\frac{p_{\mathrm{He}}}{p_{\mathrm{CH}_4}} \times \sqrt{\frac{16}{4}}=\frac{2 p_{\mathrm{He}}}{p_{\mathrm{CH}_4}}=\frac{2 \times 16}{4}=8\)

∴ The ratio of the number of moles of He and CH₄ (composition) in the initial gas mixture effused out 8:1

Question 7. ‘X’ and ‘ Y’ are the two open ends of a glass tube with a length of lm. NH₃ gas through ‘X’ and HCl gas through ‘Y’ are simultaneously allowed to enter the tube. As NH₃ and HCl gases diffuse towards each other inside the tube, they meet and react to form NH₄Cl(s), as a result of a white fume appears. Where will the white fume appear first inside the tube?
Answer:

Suppose, NH₃ gas first comes in contact with HCl gas after it traverses a distance of f cm from the X-end of the tube. At the same time, HCl gas moves a distance of (100-f) cm from the K-end of the tube. Therefore, the first white fume, appearing due to the formation of NH₄Cl(s) from the reaction of NH₄ with HCl, will be seen tit u distance of f cm f/otn the X -end.

If r₁ and r₂ are the rates of diffusion of Nil., and HCI respectively, then

⇒ \(r_1=\frac{l}{t} \text { and } r_2=\frac{(100-t)}{t}\)

∴ \(\frac{r_1}{r_2}=\sqrt{\frac{M_{\mathrm{HCl}}}{M_{\mathrm{NH}_3}}}\)

Or, \(\frac{l}{100-l}=\sqrt{\frac{36.5}{17}} \text { or, } \frac{l}{100-l}=1.465\) or, l = 59.43 cm

So, the white fume first appears at a distance of 59.43 cm from the ‘X’-end ofthe tube

The Kinetic Theory Of Gases

The kinetic theory of gases Is based on some postulates to elucidate the behaviour of Ideal gases, This theory was first proposed by Bernoulli and was considerably extended and elaborated by Clausius, Boltzmann, Maxwell, van der Waals arid Jeans.

Fundamental Postulates Of Kinetic Theory Of Gases

• A gas consists of a large number of tiny discrete particles, called molecules.
• The gas molecules are solid, spherical and perfectly elastic.
• Molecules of a gas are alike In all respects.
• The actual volume occupied by the molecules Is negligible in comparison to the volume of the container.
• Gas molecules are always in ceaseless chaotic motion.
• They constantly collide with each other and with the walls of the container. Collisions of gas molecules with the walls of the container give rise to (lie pressure of a gas.
• All molecular collisions are perfectly elastic i.e., during collisions, molecules do not gain or lose kinetic energy.
• There exist no forces of attraction or repulsion among (lie gas molecules, l, a., molecules in a gas behave Independently of one another.
• The average kinetic energy of the molecules of a gas is directly proportional to the absolute temperature ofthe gas.

Justification for the postulates of the kinetic theory of gases:

• According to the kinetic theory of gases, the total volume of the gas molecules is negligible compared to the volume of the container holding the gas. This means that most of the volume occupied by a gas in a container is empty. The high compressibility of gases justifies this assumption.
• The kinetic theory of gases proposes that the gas molecules are always in ceaseless random motion.
• If the molecules of a gas were not in ceaseless random motion, the gas would have a definite shape and size. But in fact, gases do not have a definite shape and size, which supports the ceaseless random motion of gas molecules.

According to the kinetic theory of gases, there exists no force of attraction or repulsion among gas molecules. The indefinite expansion of a gas supports this postulate.

• The kinetic theory of gases tells us that the pressure of a gas arises due to the collisions of gas molecules with the walls of the container. Molecule In a gas his terms that move randomlyIn straight lines In all directions.
• As a result, they constantly collide with one another and with the walls of the container. The force exerted by the molecules unit area of the wall of the container represents the pressure of the gas.
• The collisions of gas molecules among themselves and also against the walls of the container are perfectly elastic. This means there Is no loss or gain of kinetic energy during collisions, i.e., the total kinetic energy of the gas molecules before and after collisions remains the same.

If the kinetic energy of the gas molecules enclosed in an insulated container were not conserved during collisions, the pressure of the gas In that insulated container would also fluctuate.

• But, the fact is that the pressure of the gas enclosed In an insulated container remains the same. So, this confirms that the collisions of gas molecules among themselves and with the walls of the container are perfectly elastic.
• According to the kinetic theory of gases, the average kinetic energy of gas molecules is proportional to the absolute temperature of the gas. With increasing temperature, the pressure of a gas increases at constant volume.
• Again, the pressure of a gas increases as the number of collisions of the gas molecules with the walls ofthe container increases, which in turn, increases with the increase in average kinetic energy of gas molecules.
• Thus, it can be concluded that the average kinetic energy of the gas molecules is proportional to the absolute temperature of the gas.

Kinetic gas equation

Based on the postulates of the kinetic theory of gases, an equation for the pressure of a gas can be deduced. This equation is known as the kinetic gas equation.

The equation is \(P=\frac{1}{3} \frac{m n c_{r m s}^2}{V}\)

Where P and V are the pressure and volume of tyre gas, arms are the root mean square velocity of the gas molecules, m = mass of each gas molecule, and n – is the number of molecules present in volume V.

Average velocity and mean square velocity

Let, the total number of molecules in a sample of gas be n. Of these molecules, suppose, n, molecules move with velocity c₁, c₂, molecules move with velocity c₂, n₃ molecules move with velocity c₃, and so on.

Average velocity:

It is the arithmetical mean of the velocities of all the molecules in a gas at a given temperature.

Average velocity, \(\bar{c}\)

= \(\frac{n_1 c_1+n_2 c_2+n_3 c_3+\cdots}{n_1+n_2+n_3+\cdots}\)

= \( \frac{n_1 c_1+n_2 c_2+n_3 c_3+\cdots}{n}\)

‘Bar’(-) over c indicates the average value of c]

If the absolute temperature and the molar mass of a gas are T and M, respectively, then it can be shown that

⇒ \(\bar{c}=\sqrt{\frac{8 R T}{\pi M}}.\)

Mean square velocity:

It is the arithmetical mean of the square velocities of all the molecules in a gas at a given temperature.

Mean square velocity

⇒ \(\overline{c^2}=\frac{n_1 c_1^2+n_2 c_2^2+n_3 c_3^2+\cdots}{n_1+n_2+n_3+\cdots}\)

= \(\frac{n_1 c_1^2+n_2 c_2^2+n_3 c_3^2+\cdots}{n}\)

Root mean square velocity

The square root of the mean square velocity of the molecules in a gas at a given temperature is called the root mean square (RMS) velocity. Root mean square velocity

⇒ \(c_{r m s}=\sqrt{\overline{c^2}}=\sqrt{\frac{n_1 c_1^2+n_2 c_2^2+n_3 c_3^2+\cdots}{n}}\)

The average velocity (c) and the root mean square velocity of the molecules of a gas are not the Suppose, we have 2 molecules with velocities 2 m-s^-1 and 4 m-s^-1, respectively. The average velocity of the two molecules,

⇒ \(c=\frac{(2+4) \mathrm{m} \cdot \mathrm{s}^{-1}}{2}=3 \mathrm{~m} \cdot \mathrm{s}^{-1}\)

And root mean square velocity

⇒ \(c_{t \mathrm{~ms}}=\sqrt{\frac{2^2+4^2}{2}}=3.16 \mathrm{~m} \cdot 5^{-1}\)

To determine the tbs average kinetic energy of gas molecules, the root mean square velocity is used instead of the average velocity

Gases are isotropic i.e. the properties of gases are Independent of direction. So, gas molecules can move in all directions with equal probability.

Therefore, the average velocity of the gas molecules along a particular axis (x or y or z )is zero because at any instant the probability ofthe number of molecules moving along the positive x-axis and the negative x-axis is equal.

• As a result, the average velocity along the x-axis (similarly y-axis or z-axis) becomes zero.
• For this reason, the average velocity is not used to determine the average kinetic energy of the gas molecules.
• On the other hand, the root mean square velocity of the gas molecules is determined from their mean square velocity.
• As the square of a positive or negative quantity Is always a positive quantity, the root mean square velocity is always positive.
• Hence, the root-mean-square velocity is used to determine the average kinetic energy of the gas molecules.

Determination of C_rms from the kinetic gas equation:

From the kinetic gas equation we have \(P V=\frac{1}{3} m n c_{r m s}^2\)

P and V are the pressure and volume of gas respectively, at a particular temperature, arms are the root mean square velocity of molecules in the gas at the same temperature, m is the mass of the gas molecule and n is the number of molecules present in volume V. For 1 mol gas, n = N (Avogadro’s number)

Therofore P V=\frac{1}{3} m N c_{r m s}^2 \text { (for } 1 \mathrm{~mol} \text { gas). }\(\)

Molar mass (M) of a gas = mass of each molecule of the gas x Avogadro’s number =mN and for 1 mole of gas, PV = RT.

Therefore. \(R T=\frac{1}{3} M c_{r m s}^2\) or, \(c_{r m s}=\sqrt{\frac{3 R T}{M}}\)

This equation represents the root mean square velocity at a given temperature T of the molecules in a gas with a molar mass of M.

It is evident from this equation that the root mean square velocity of the molecules of a gas is directly proportional to the square root of absolute temperature and inversely proportional to the square root of the molar mass of the gas.

If the molar masses of A and B gases are M_A and M_B respectively and the root mean square velocities of the molecules of A and B and (arms), respectively, then at a particular temperature (T),

⇒ \(\left(c_{r m s}\right)_A=\sqrt{\frac{3 R T}{M_A}} \text { and }\left(c_{r m s}\right)_B=\sqrt{\frac{3 R T}{M_B}}\)

So, \(\frac{\left(c_{r m s}\right)_A}{\left(c_{r m s}\right)_B}=\sqrt{\frac{M_B}{M_A}}\)

Therefore, at a particular temperature is greater for a lighter gas. For example, at a given temperature c value for H2 molecules is 4 times as high as that of O2 molecules

⇒ \(\frac{\left(c_{r m s}\right)_{\mathrm{H}_2}}{\left(c_{r m s}\right)_{\mathrm{O}_2}}=\sqrt{\frac{32}{2}}=\sqrt{16}=4\)

Or, \(\left(c_{r m s}\right)_{\mathrm{H}_2}=4 \times\left(c_{r m s}\right)_{\mathrm{O}_2}\)

Most probable velocity (c_m)

Gas molecules move randomly in all directions, collide with each other and also against the walls oftheir container. Due to such frequent collisions, there is always a redistribution of velocities among the molecules.

At any instant in time, the gas contains molecules moving with very high to very low velocities. Maxwell, by extensive mathematical calculation of the distribution of molecular velocities, has shown that at a particular temperature, the velocity with which the maximum fraction of molecules in a sample of gas move has a constant value. This velocity is known as the most probable velocity and it is represented by the equation.

⇒ \(c_m=\sqrt{\frac{2 R T}{M}}\)

Where T and M are the absolute temperature and molecular mass ofthe gas respectively.

Relation among different molecular velocities: At a given temperature T the average velocity (c), root mean square velocity (arms) and most probable velocity (cm) of the molecules ofa gas with molar mass M are-

⇒ \(\bar{c}=\sqrt{\frac{8 R T}{\pi M}}, c_{r m s}=\sqrt{\frac{3 R T}{M}} \text { and } c_m=\sqrt{\frac{2 R T}{M}}\)

∴ \(\left[c_m: \overline{\boldsymbol{c}}: c_{r m s}\right]=\sqrt{\frac{2 R T}{M}}: \sqrt{\frac{8 R T}{\pi M}}: \sqrt{\frac{3 R T}{M}}\)

⇒ \(=\sqrt{2}: \sqrt{\frac{8}{\pi}}: \sqrt{3}=1: 1.128: 1.224\)

Relation between c and C_rms:

At a definite temperature, for a particular gas c_m =c_rms = 0.921

Average velocity = 0.921 × root mean square velocity.

The relation between c_m and arms is c_m / arms  = 0.816

Most probable -velocity = 0.816 × root mean square velocity

For the gas molecules of a given gas at a definite temperature,

c_rms>c‾>c_m

Average kinetic energy of gas molecules

Since all the molecules in a gas do not move at the same velocity, they do not have the same kinetic energy. Thus, the kinetic energy of the molecules in ofa gas is always expressed in terms of average kinetic energy.

Let n be the total number of 6 molecules in a sample of gas, and m be the mass of each molecule. If at a given temperature, molecules move with velocity c₁, n₂ molecules with velocity c₂, n₃ molecules with velocity c₃— etc., and the respective kinetic energies of these molecules are \(\epsilon_1, \epsilon_2, \epsilon_3 \ldots\) etc., then

⇒ \(\epsilon_1=\frac{1}{2} m c_1^2, \epsilon_2=\frac{1}{2} m c_2^2, \epsilon_3=\frac{1}{2} m c_3^2 \cdots e t c .\)

Therefore, the average kinetic energy of the molecules,

⇒ \(\bar{\epsilon}=\frac{n_1 \epsilon_1+n_2 \epsilon_2+n_3 \epsilon_3+\cdots}{n}\)

⇒ \(=\frac{1}{2} m\left[\frac{n_1 c_1^2+n_2 c_2^2+n_3 c_3^2+\cdots}{n}\right]=\frac{1}{2} m \overline{c^2}\)

Also, mean square velocity = (root mean square velocity)2 i.e., \(\overline{c^2}=c_{r m s}^2\)

∴ Average kinetic energy of a gas molecule \(=\frac{1}{2} m c_{r m s}^2\)

Equation [1] expresses the relation between the average kinetic energy and the root mean square velocity of the molecules in a gas.

Value of average kinetic energy:

The average kinetic energy of the molecules in a gas at a particular temperature,

⇒ \(\bar{\epsilon}=\frac{1}{2} m c_{r m s}^2\) where m is the mass of a gas molecule, cms is its root mean square velocity At a given temperature for the molecules in a gas,

⇒ \(c_{r m s}=\sqrt{\frac{3 R T}{M}}=\sqrt{\frac{3 k \times N \times T}{m \times N}}=\sqrt{\frac{3 k T}{m}}\)

Since Molar mass (M) of a gas = mass of a molecule (m) of the gas Avogadro’s’ number (N) and R = k (Boltzmann constant) × N]

∴ \(\bar{\epsilon}=\frac{1}{2} m c_{r m s}^2=\frac{1}{2} \times m \times \frac{3 k T}{m}=\frac{3}{2} k T\)

It is evident from this equation that the average kinetic energy of the gas molecules is proportional to the -absolute temperature. Therefore, at TK, the total kinetic energy of the molecules of1 mol ofa gas.

⇒ \(=\epsilon \times N=\frac{3}{2} k T \times N=\frac{3}{2} R T\)

[since r = k × N]

CBSE Class 11 Chemistry States of Matter Liquids Gases Summary

Numerical Examples

Question 1. Determine the ratio of root mean square velocity and average velocity of the molecules in a gas at a given temperature
Answer:

If M and T are the molar mass and temperature ofthe gas, then the root mean square velocity \(c_{r m s}=\sqrt{\frac{3 R T}{M}}\) and the average velocity, \((\bar{c})=\sqrt{\frac{8 R T}{\pi M}}\)

∴ \(\frac{c_{r m s}}{c}=\sqrt{\frac{3 \pi}{8}}=1.085\)

Question 2. Show that the root mean square velocity of an O₂ molecule at 54°C is not twice its root mean square velocity at 27°C
Answer:

At 54°C, i.e., at (273 + 54)K = 327K the root mean square velocity of O₂ molecules,

⇒ \(\left(c_{r m s}\right)_1=\sqrt{\frac{3 R T}{M}}=\sqrt{\frac{3 \times 8.314 \times 10^7 \times 327}{32}}\)

= 5.048 × 10⁴ cm-s^-1

And at 27°C i.e., at (273 + 27)K = 300K

⇒ \(\left(c_{r m s}\right)_2=\sqrt{\frac{3 R T}{M}}=\sqrt{\frac{3 \times 8.314 \times 10^7 \times 300}{32}}\)

=4.835 × 10⁴  cm.s^-1

∴ (arms)1≠2(c_rms)².

Question 3. Determine the rms velocity, average velocity and most probable velocity of H₂ molecules at 300 K.
Answer:

Molar mass (M) of H₂ gas = 2g.mol^-1

∴ Root mean square velocity of H₂ molecule

⇒ \(\sqrt{\frac{3 R T}{M}}=\sqrt{\frac{3 \times 8.314 \times 10^7 \times 300}{2}}=1.934 \times 10^5 \mathrm{~cm} \cdot \mathrm{s}^{-1}\)

Average velocity = \(=\sqrt{\frac{8 R T}{\pi M}}=\sqrt{\frac{8 \times 8.314 \times 10^7 \times 300}{3.14 \times 2}} ;\)

= 1.782×105 cm.5 cm.s^-1

Most probable velocity \(\sqrt{\frac{2 R T}{M}}=\frac{2 \times 8.314 \times 10^7 \times 30}{2}\)

= 1.58 × 10 ⁵cm.s^-1

Question 4. At what temperature will the most probable velocity of the H₂ molecule be equal to the root mean square velocity of O₂ molecules at 20°C?
Answer:

At 20°C temperature, the root mean square velocity of the O2 molecule =

⇒ \(\sqrt{\frac{3 R T}{M}}=\sqrt{\frac{3 \times 8.314 \times 10^7 \times(273+20)}{32}} \mathrm{~cm} \cdot \mathrm{s}^{-1}\)

Let at temperature T₁ the most probable velocity of H₂ = the rms velocity of O₂ at 20°C.

At TK, the most probable velocity of H₂

⇒ \(\sqrt{\frac{2 R T}{M}}=\sqrt{\frac{2 \times 8.314 \times 10^7 \times T}{2}} \mathrm{~cm} \cdot \mathrm{s}^{-1}\)

∴ \(\sqrt{\frac{2 \times 8.314 \times 10^7 \times T}{2}}=\sqrt{\frac{3 \times 8.314 \times 10^7 \times 293}{32}}\)

or, \(T=\frac{3 \times 293}{32}=27.50\) Therefore at —245.5°C, the most probable velocity of H2 molecules will be equal to the rms velocity of 02 at 20 °C.

Question 5. The density of O₂ gas at 1 atm pressure and 273K is 1.429 g-dm-3. Calculate the root mean square velocity of 02 molecules at 273 K
Answer:

The root mean square velocity,

⇒  \(c_{r m s}=\sqrt{\frac{3 R T}{M}}=\sqrt{\frac{3 P V}{M}}=\sqrt{\frac{3 P}{d}}\)

Given, P = 1 atm and d = 1.429 g-dm^-3

P = latm = 1.013 × 10⁶ dyn-cm^-2

= 1.013 × 10^-6 g.cm.s^-2 .cm^-2 = 1.013 × 10⁶ g. cm^-1.s^-2

and d = 1.429 g.dm^-3 = 1.429 × 10^-3 g.cm^-3

∴ \(c_{r m s}=\sqrt{\frac{3 \times 1.013 \times 10^6 \mathrm{~g} \cdot \mathrm{cm}^{-1} \cdot \mathrm{s}^{-2}}{1.429 \times 10^{-3} \mathrm{~g} \cdot \mathrm{cm}^{-3}}}\)

= 4.611 × 10⁴ cm.s^-1

Question 6. Determine the total kinetic energy of the molecules of 1 g CO₂ at 27°C in the units of erg and calorie. Assume the ideal behaviour of the gas.
Answer:

1 g \( \mathrm{CO}_2=\frac{1}{44}=2.27 \times 10^{-2} \mathrm{~mol} \mathrm{CO}_2 \text { and }\)

T = (273 + 27)K = 300 K

The total kinetic energy of the molecules in mol of an ideal gas.

⇒ \(\frac{3}{2} R T\)

Therefore, the total kinetic energy of the molecules of

⇒ \(2.27\times 10^{-3} \mathrm{~mol}\)

CO₂ gas = \(2.27 \times 10^{-2} \times \frac{3}{2} R T\)

= \(2.27 \times 10^{-2} \times \frac{3}{2} \times 8.314 \times 10^7 \times 300\)

= \(8.5 \times 10^8 \mathrm{erg}\)

= 20.31cal

= 8.5 ×  10⁸ erg = 20.31 cal

Since 1 cal = 4.18 × 10⁷erg

Question 7. Determine the total kinetic energy of the molecules of 8.0 g CH₄ at 27°C in the unit of joule.
Answer:

8.0 = \(\mathrm{CH}_4=\frac{8}{16}=0.5 \mathrm{molCH}_4\)

since MCH₄ = 16g.mol^-1]

Total kinetic energy ofthe moleculesin1 mol gas \(=\frac{3}{2} R T\)

∴ Total kinetic energy ofthe molecules of 0.5 mol CH₄ gas

⇒ \(=0.5 \times \frac{3}{2} R T=0.5 \times \frac{3}{2} \times 8.314 \times(273+27)=1870.65 \mathrm{~J} .\)

Question 8. At a given temperature, the average kinetic energy of H₂ molecules is 3.742 kj. mol^-1. Calculate the root mean square velocity of H₂ molecules at this temperature
Answer:

Suppose, at TK, the average kinetic energy of H₂ gas molecules =3.742 kj.mol-1.

∴ \(\frac{3}{2} R T=3.742 \times 10^3 \mathrm{~J} \cdot \mathrm{mol}^{-1}\)

or, \(\frac{3}{2} \times 8.314 \times T=3.742 \times 10^3\)

∴ t= 300k

Therefore, the root mean square velocity of the H2 molecule

⇒ \(\text { at } 300 \mathrm{~K}=\sqrt{\frac{3 R T}{M}}=\sqrt{\frac{3 \times 8.314 \mathrm{~J} \cdot \mathrm{mol}^{-1} \cdot \mathrm{K}^{-1} \times 300 \mathrm{~K}}{2 \mathrm{~g} \cdot \mathrm{mol}^{-1}}}\)

⇒ \(=\sqrt{\frac{3 \times 8.314 \times 10^3 \mathrm{~g} \cdot \mathrm{m}^2 \cdot \mathrm{s}^{-2} \times 300}{2 \mathrm{~g}}}=1934.2 \mathrm{~m} \cdot \mathrm{s}^{-1}\)

Maxwell’s distribution of velocity

In a collection of gas molecules, there exists a wide distribution of velocity, ranging from very low to very high value. Molecules moving with very low to very high velocities are very small. Most of the molecules move with intermediate velocities.

Maxwell showed that the molecular velocity distribution in a gas depends on the temperature and molar mass of the gas and gave an equation, commonly known as Maxwell’s distribution law of molecular velocity.

According to this law, at a given temperature, the distribution of velocities remains the same although individual velocities of gas molecules may change due to collision. Let the total number of molecules in a gaseous sample be n and at a particular temperature, dn is the number of molecules having velocities in the range c to c + dc \(\left(\frac{d n}{n}\right)\) is a small interval of velocity).

Tints, the fraction of molecules having velocity in the range c to c + dc is \(\left(\frac{d n}{n}\right)\). The value of f changes with a change in the value of c. Maxwell’s distribution is obtained by plotting

⇒ \(\left(\frac{d n}{n}\right)\) as ordinate and c as abscissa.

Description of the graph:

The given graph shows that the fraction of molecules \(\left(\frac{d n}{n}\right)\) increases with c, reaches a maximum, and then decreases rapidly. The velocity corresponding to the maximum in the distribution curve indicates the velocity possessed by most of the molecules.

This velocity is called the most probable velocity (cm). For a gas with molar mass M, the most probable velocity of its molecules at temperature T is:

⇒ \(c_m=\sqrt{\frac{2 R T}{M}}\)

The number of molecules moving with very high or very low velocities is very small.

The average velocity of the molecules is slightly greater than the most probable velocity and the root mean square velocity is still slightly greater than the most probable velocity.

Effect of molar mass on the distribution of molecular velocity at constant temperature:

According to the equation \(c_m=\sqrt{\frac{2 R T}{M}}\) at a given temperature, the most probable velocity of molecules of a gas is inversely proportional to the molar mass of the gas.

Therefore, at a particular temperature, the most probable velocity of a gas with a larger molar mass will be lower than that of a gas with a smaller molar mass, and the maxima in the distribution curve for a lighter gas will occur at a higher velocity than that for a heavier gas. As a result, the curve for a lighter gas becomes more flattened than that for a heavier gas.

Influence of temperature on velocity distribution:

The change in temperature changes the velocity of the molecules. As a result, the distribution of molecular velocities also changes The velocity distribution curves at three different temperatures (T₁, T₂ and T₃ ) are given below.

With increasing temperature, the curve gets flattened and the maximum the curve shifts to the right. This means that with temperature rise, the most probable velocity (cm) of the molecules increases although the number of molecules moving with this velocity decreases. Thus, the velocity distribution curve broadens at higher temperatures.

The middle portion of the curve gets flattened with the increase in temperature. This indicates that with an increase in temperature, the number of molecules with higher velocity increases and that with lower velocity decreases.

If the temperature decreases, the distribution curve becomes gradually narrow and the most probable velocity of the molecules decreases, while the number of molecules with this velocity increases.

Deviation Of Real Gases From Ideal And Behaviour

The equation of state for n mol of an ideal gas is PV = nRT. In practice, there is no such gas which obeys PV = nRT under all conditions of pressure and temperature. Gases which do not obey the equation, PV = nRT, except at very low pressure and high temperature, are said to be real gases. All naturally occurring gases are real gases. Fegnault, Andrews, Amagat, KamerJing and other scientists have studied the deviation of real gases from ideal behaviour.

Amagat curves

Amagat carried out an extensive study on the behaviour of real gases. From the results of his observations, he plotted PV against constant temperature for different gases.

If the gas obeys the equation, PV = NRT (ideal gas), then at a constant temperature, the PV vs P plot will be a straight line parallel to the P-axis and at any temperature, and the value of PV will be equal to that of RT (forI mol of gas). This is shown by a dotted line. In the case of real gases, however, the plots of PV vs P are not a horizontal line Instead they deviate from the line of ideas gas and take a curve-like shape as shown by unbroken lines.

The curves for real gases are of two types. These are—

In the case of gases like N₂, CO₂ etc., with the increase in pressure, the value of PV initially decreases from the expected value of nRT, passes through a minimum and then goes on increasing, even after exceeding the value of nRT.

Such gases show a negative deviation in the beginning, reach a minimum value and then show a positive deviation after crossing the line for ideal gas. Depression in the curve of gas is characteristic ofthe gas and it also depends on the experimental temperature.

For gases like H₂, He etc., the value of PV increases with pressure right from the beginning. No depression appears in their curves. Although at 0°C, the PV vs P curves obtained in the case of H₂ and He etc. do not have any depression or concave part, they become identical to those obtained for gases like N₂ and O₂ etc.

When PV values for H₂ and He is measured at temperatures below their respective Boyle temperatures. PV vs P isotherms at different pressures upto 1 atm are found to be straight lines but they are not parallel to the P -axis.

Keeping the temperature fixed at 0°C, when PV vs P curves for mol of different real gases at various pressures upto 1 atm are drawn and extrapolated, it is observed that all the straight lines meet the PV-axis at 22.424 L-atm value at P = 0 J. This value of PV for any real gas is equal to the value of PV for 1 mol ideal gas at STP.

So, at extremely low pressure (P→ 0), real gases exhibit ideal behaviour

Deviations Concerning pressure:

For real gases, the deviations from ideal behaviour concerning pressure can be studied by plotting pressure vs volume at a given temperature. If we plot experimental values of pressure vs volume at constant temperature (i.e., for real gas) and p theoretically calculated values from Boyle’s law (i.e., for ideal gas) the two curves do not coincide.

From this plot, we observe that at very high pressure, the volume of the real gas is more than that of an ideal gas. Pressure, these two volumes approach each other.

Deviation from ideal behaviour and Boyle temperature:

For a given gas, if PV vs P curves at different fixed temperatures are drawn, then it is found that with the increase in temperature, the depths in the curves gradually decrease (curves become more and more flat) along with the simultaneous shifting of the minimum values of PV to the left.

For every gas, there is a certain temperature, characteristic of the gas, at which the PV-P coincides with the line ofthe ideal gas over an appreciable range of pressure. This temperature is called the Boyle temperature of the gas.

This is so called because the PV value for the gas remains constant over the range of pressure indicating that the gas obeys Boyle’s law.

Boyle temperature

For any real gas, there is a certain temperature, characteristic of the gas, at which the gas follows the ideal gas laws over a wide range of pressure.

This temperature is called the Boyle temperature ( TB) or Boyle point of the gas. The Boyle temperature for gas following the van der Waals equation is given by the relation given by, \(T_B=\frac{a}{R b}\)

Alternative definition:

The temperature at which the plot of PV vs P for areal gas results in a line parallel to the P-axis over an appreciable range of pressure, is called the Boyle temperature of the gas.

Alternatively, the particular temperature at which the value of PV for a real gas becomes constant over an appreciable range of pressure is called the Boyle temperature of that gas. -Ideal gas -Real gas V-

The values of Boyle’s temperature are different for different gases. For example—the Boyle temperatures of H₂ and N₂ are -156°C and 50°C, respectively. Generally, the liquefaction of a gas becomes easier for a gas having a higher Boyle temperature.

Boyle temperatures for most of the gases are found to be higher than the ordinary temperature. For this reason, a concave region is found in the PV vs P plots of N₂ O₂ CH₄ etc. gases at ordinary temperature.

On the other hand, such kind of concave region is absent in the case of the PV vs P plots of H₂ and He gases as their Boyle temperatures are much lower than the ordinary temperature. However, such plots for H₂ and He gases at temperatures below their respective Boyle temperatures exhibit minima.

Conclusion:

A real gas behaves like an ideal gas at very low and high temperatures. Exhibits a large 10- 10-pressure deviation from ideal behaviour at very high pressures and low temperatures. Behaves like an ideal gas at its Boyle temperature over a wide range of pressure.

Compressibility factor of real gases

Looking at the reveals that in the high-pressure region, for a given value of pressure, the value of PV for a real gas is larger than that for an ideal gas. On the other hand, in the low pressure, region at a given pressure, the value of PV is smaller than that for an ideal gas.

The different values of PV for a real gas and an ideal gas imply that a real gas deviates from the behaviour of an ideal gas. The extent of deviation of a real gas from the ideal behaviour is usually expressed in terms of a quantity, called the compressibility factor.

The equation of state for n mol of an ideal gas, PV = nRT. However, the equality of PV and nRT does not hold well for a real gas so PV nRT. Let, in the case of a real gas PV = Zx nRT; where Z= compressibility factor. Therefore

⇒ \(\mathrm{Z}=\frac{P V}{n R T}\)

For an ideal gas, PV = nRT, hence Z = 1 For areal gas, PVnRT, hence Z ≠1

Let at pressure P and temperature T, the volume for nmol of an ideal gas be V1 and that forn mol of a real gas be V.

For an ideal gas, Z = 1, so, 1 =\(\frac{P V_i}{n R T} \text { or, } n R T=P V_i\)

=\(\frac{P V_i}{n R T} \text { or, } n R T=P V_i\)

∴ \(Z=\frac{P V}{n R T}=\frac{P V}{P V_i}=\frac{V}{V_i}\)

⇒ \(\frac{\text { at a given pressure and temperature the volume of nmol of a real gas}}{\text { the volume of n mol of an ideal gas at the same pressure and temperature } { }}\)

When V = V_i, Z = 1; i.e., the real gas behaves like an ideal gas.

When V> V_i, Z> 1; i.e., under the same conditions of temperature and pressure, the real gas is less compressible than the ideal gas and it deviates from ideal behaviour. This type of deviation is called positive deviation.

When V<V_i, Z <l; i.e., under the same conditions of temperature and pressure, the real gas is more compressible than the ideal gas and it deviates from ideal behaviour. This type of deviation is called negative deviation.

Therefore, when a real gas deviates from the ideal behaviour, its value of Z becomes greater than or less than 1. Z vs P plots for several reed gases at 0°C are given below From the plots, it is found that for N₂, CO₂, CH₂tc., the values of Z at very low pressures are very close to 1 Hence at very low pressures, these gases behave nearly like ideal gas.

Causes of deviation of real gases from ideal behaviour

The Dutch scientist van der Waals explained the causes of the deviation of real gases from ideal behaviour. He mentioned two faulty assumptions ofthe kinetic theory ofgases. These are-

1. In the kinetic theory of gases, the gas molecules are considered point particles of very small dimensions, and the total volume occupied by them is negligible compared to the volume of their container.
2. But actually, a gas molecule always has a finite volume although it is extremely small. Thus, in a real gas, the actual volume available to the molecules for free movement is somewhat less than the volume of the container in which the gas is kept.
3. According to the kinetic theory of gases, the molecules in a gas do not experience any intermolecular forces of attraction. But, this is not true as this is evident from the fact that a real gas always exerts less pressure than that calculated for an Ideal gas under an identical set of conditions.

The gas molecules in a real gas occupy a certain volume and they do feel intermolecular forces of attraction. By applying pressure or decreasing temperature, a gas can be converted into a liquid or a solid. Since a liquid or a solid has molecules in a gas, then it would not be possible to condense a gas into a liquid or a solid.

Difference Between Ideal gas and Real gas:

Explanation of the plot of \(Z\left(=\frac{P V}{n R T}\right)\) vs P:

The reasons for the deviation of real gases from ideal behaviour are— low-pressure region, the effect of intermolecular attractive forces predominates over the effect of the volume of gas molecules der Waals equation van der Waals pointed out two faulty assumptions in the kinetic theory of gases as the cause for the failure of real gases to obey the Ideal gas equation.

These faulty assumptions are -volume assumptions and pressure assumptions. He modified the equation, PV m to rectify those two defects and presented a revised equation which Is widely known as the van Dor Winds equation.

Volume correction:

Let us consider, n moles of a real gas enclosed in a container of volume V at temperature 7’K. As each ofthe gas molecules occupies a definite volume the entire space in the container Is not available to them for free movement. So, the space available for free movement will be somewhat less than (the volume of the container, if the total volume of 1-mole molecules is then the volume for n moles molecules will be’ nb Here the term ‘b’ Is called volume correction term or co-volume or excluded volume.

Therefore, the corrected volume available for the motion ofthe molecules = (V -nb).

The quantity ‘b‘ is related to the actual volume of the gas molecules. It can be shown by calculation that the value of ‘b’ is four times the total volume of mole molecules. If the radius of each gas molecule is r, then, the volume of each molecule \(\frac{4}{3} \pi r^3\).

∴ The total volume of 1 mol molecules

⇒  \(N \times \frac{4}{3} \pi r^3[N=\text { Avogadro no. }]\)

Therefore \(b=4 \times N \times \frac{4}{3} \pi r^3\)

Pressure correction:

According to the kinetic theory of gases, there exist no attractive forces among the molecules in a gas. But, it has been proved by different experiments that intermolecular attractions exist among the gas molecules. A molecule (A) in the bulk of a gas is surrounded by other molecules and attracted equally from all directions.

Consequently, the net force on this. The molecule is zero. However, the situation is different for molecule (B) near the wall of the vessel. Here, the molecule ‘B’ is attracted towards the centre by the molecules inside the vessel. So, the force with which the molecule strikes the wall is less than that with which it would strike if there were no intermolecular forces of attraction. Thus the observed pressure, (P) of the gas will be lower than that calculated for an ideal gas Pi.

Hence, the ideal pressure (P_i) can be obtained if we add a correction term (P_a) to the observed pressure. Therefore, P. = P_i+ P_a Here, P a is the measure of cohesive force due to the intermolecular forces of attraction. It can be shown by calculation, Pa = (n²a)/V²; where n and V are the moles and the volume of the gas respectively and a = constant.

⇒ \(\left(P+\frac{n^2 a}{V^2}\right)\) or Pi and (V- nb)

For the ideal gas equation P_iV_i = nRT, we get, reduce

⇒ \(\left(P+\frac{n^2 a}{V^2}\right)(V-n b)=n R T\)

This is the van der Waals equation for nmol of real gas

If n=1, then \(\left(P+\frac{a}{V^2}\right)(V-b)=R T\)

This is the van der Waals equation for 1 mol of areal gas. In this equation, P and V are the pressure and volume of 1 mol of a real gas, respectively, at temperature, TK.

The explanation for the deviation of real gases from ideal behaviour by the van der Waals equation

Amagat’s curves indicate the deviation of real gases from ideal behaviour. The nature of Amagat’s curves as well as the behaviour of a real gas at different temperatures and pressures can be explained by the van der Waals equation.

For mol of a real gas, the van der Waals equation is:

⇒ \(\left(P+\frac{a}{V^2}\right)(V-b)=R T\)

let us see the forms of this equation in the following special cases

At very low pressure:

At very low pressure, as the volume (V) of a gas is very large, the value of ‘b’ Is negligible compared to V i.e., {V- b) « V. So, the van der Waals equation becomes-

⇒ \(\left(P+\frac{a}{V^2}\right) V=R T \quad \text { or, }\left(P V+\frac{a}{V}\right)=R T \text { or, } P V=R T-\frac{a}{V}\)

Thus, at a very low pressure, the value of PV is less than that of RT. Also, with pressure increases, the volume (V) of a gas decreases, and hence the value of (a/V) increases. As a result, the value of PV decreases with an increase in pressure. In Amagat’s curves for gases like N₂, CO₂, CH₄ etc., the initial decrease in the value of PV with an increase in pressure can thus be explained.

At very high pressure:

At very high pressure, the volume (V) of a gas is very small, and the value of the gas cannot be neglected in comparison to V. But the value of a/V2 is very small in comparison to P, and hence \(\left(P+\frac{a}{V^2}\right) \approx P\)

Therefore, the van der Waals equation reduces to P(V- b) = RT or, PV = RT+Pb From this equation, it is seen that the value of PV is greater than RT. The value of Pb increases with an increase in pressure. Consequently, the value of PV goes on increasing. This explains the continuous increase of PV with pressure in the Amagat’s curves, for gases like N₂, CO₂, CH₄ etc.

Exceptional behaviour of H₂ and He gases:

Because of the very small molar masses of H2 and He, the strength of molecular forces attracting these gases is very weak, and hence the value of V2 at any value of P can be neglected. So, the van der Waals equation for these gases can be expressed as P(V-b) = RT or, PV = RT+Pb. This equation shows that the value of PV is always greater than RT. Thus, PV for H2 and He increases linearly with pressure from the very beginning.

Causes (or ideal, behaviour of real gases at very low pressure and high temperature:

At a very low pressure, the volume ( V) as well as the intermolecular distances among the gas molecules is very large. As a result, the intermolecular forces of attraction become very weak, making the value of ‘a’ negligible.

Thus, the value of the term a/V₂ becomes negligible at very low pressure because of the very large value of V and the very small value of a So, the term a V2 can be ignored in comparison to P. The term b can be neglected in comparison to V because of the large value of V.

Therefore, at very low pressure \(P+\frac{a}{V^2} \approx P \text { and } V-b \approx V \text {. }\) In this condition, the van der V2 Waals equation reduces to PV = RT Thus at very low pressure, areal gas behaves like an ideal gas.

At a very high temperature, the volume of a gas becomes very large and the average kinetic energy of the molecules of the gas becomes very high. Hence the intermolecular forces of attraction become insignificant. As a result, the term \(\frac{a}{V^2}\) in comparison to very high temperature therefore \(P+\frac{a}{V^2} \approx P \text { and } V-b \approx V\) So, at a very high temperature, van der Waals equation reduces to PV = RT and a real gas exhibits ideal behaviour.

van der Waals constants

The terms ‘a ‘ and ‘b’ in the van der Waals equation are called van der Waals constants. The values of these constants depend on the nature of a gas.

Significance of van der Waals constants: Significance of a: ‘a’ measures the magnitude of intermolecular forces of attraction in a gas. The stronger the intermolecular forces of attraction in a gas, the larger the value of the gas.

A gas with a larger value can be liquefied easily. Hence, the larger the value of a gas, the greater the ease of its liquefaction.

Significance of a:

The term ‘b’ for a gas gives us an idea of the size of the molecules ofthe gas. The larger the value of ‘b’ the larger the size of the gas molecules, and hence lower the compressibility ofthe gas.

Units of and ‘h’: The units of and are as follows—

Unit of a:

van der Waals equation for moles of a real gas,

⇒ \(\left(P+\frac{n^2 a}{V^2}\right)(V-n b)=n R T\)

As the term (n₂a)/v₂ is added to the pressure term, its unit will be the same as that ofthe of the pressure. Therefore, the unit of \(\frac{n^2 a}{V^2}\)\frac{n^2 a}{V^2} = unit of pressure

∴ Unit of ‘a’ = unit of pressure \(\text { unit of pressure } \times \frac{(\text { unit of volume })^2}{(\text { number of mole })^2}\)

Unit of b: As nb is subtracted from the volume, its unit will be the same as that ofthe volume. Therefore, Unit of nb = unit of volume

∴ \(\text { Unit of } b=\frac{\text { unit of volume }}{\text { number of mole }}=\mathrm{L} \cdot \mathrm{mol}^{-1}\)

Unit of ‘a’ atm- L² mol^-2   Unit of ‘b’ : L.mol^-1

Van der Waals constant of some common gases

Liquefaction Of Gases

Liquefaction of a gas is the physical transformation of the gas into its liquid state. By increasing pressure or decreasing temperature, a gas can be converted into its liquid state.

Fundamentally, the gaseous state and liquid state are different for their intermolecular distances.

• Let the molecules gaseous state be widely separated from each other but in a liquid state, they are comparatively close to each other. So, to liquefy a gas, the molecules must be brought closer to each other.
• It is possible to bring the molecules closer the pressure ofthe gases increases or their temperature decreases.
• Due to an increase in pressure, the gas molecules come closer to each other and they come under the influence of strong attractive forces.
• As a result, the gas changes into a liquid state.

On the other hand, due to a decrease in temperature, the average kinetic energy of the gas molecules decreases, which, in turn, increases the strength of intermolecular forces of attraction.

• This causes, the gas molecules to get closer to each other, and ultimately the gas changes into the liquid state.
• Andrews discovered the conditions necessary for the liquefaction of a gas. He stated that there is a particular temperature for every gas above which it cannot be liquefied no matter how high the pressure is.
• This temperature is called the critical temperature ofthe gas.
• The liquefaction ofa gas is possible only when the gas exists at or below its critical temperature.

Critical Temperature:

Every eas has a certain characteristic temperature above which the gas cannot be liquefied even if the pressure is very high. This particular temperature is called the critical temperature of the gas.

It is denoted by Tc. The liquefaction is easier for gases with high critical temperatures.

• Critical pressure: The minimum pressure required to liquefy a gas at its critical temperature is termed the critical pressure (Pc) of the gas.
• Critical volume: The volume occupied by 1 mol of a gas at its critical temperature and critical pressure is termed the critical volume (Vc) of the gas.
• Critical Constants: The values of critical temperature (Tc), critical pressure (Pc) and critical volume (Vc) are constant for a particular gas. Thus, Tc, Vc and Pc are called critical constants.

Critical temperature and pressure of some gases

The critical temperature is low for a gas whose intermolecular forces of attraction are weak. For example, the values of critical temperatures for H₂ He, O₂ etc. are very low because of their weak intermolecular forces of attraction.

The critical temperature is high for a gas whose intermolecular forces for attraction are strong. For example, the critical temperatures for CH₄, NH₃, CO, etc. are very high because of their very strong intermolecular forces of attraction.

The behaviour of a gaseous substance at its critical state Andrews was the first to investigate the behaviour of a gas in the neighbourhood of its critical temperature. He carried out his experiment on CO₂ gas and studied the variation of volume of CO₂ gas with pressure at different constant temperatures. Each curve corresponds to a constant temperature and is called an isotherm. It is evident that some isotherms lie above 31.1 °C, some below it and one at 31.1°C.

Isotherms below 31.1°C:

These isotherms have three parts. Let us consider the isotherm, ABCD corresponding to temperature Tl.

• The first part of this isotherm i.e., line AB indicates the change in volume of CO₂ gas with a change in pressure.
• Thus, AB corresponds to the gaseous state of CO₂. At point B, CO₂ gas begins to liquefy and thereafter the pressure of the system remains the same although the volume of the system goes on decreasing.
• Along line BC, the transition of CO₂ gas to liquid CO₂ takes place, and as a result, the pressure of the system remains constant.
• The line BC denotes the coexistence of gas & liquid. At point C, CO₂ completely convert into a liquid state.

At constant temperature, the liquid does not suffer any significant change in volume with pressure, so the volume change of liquid CO₂ with the increased pressure is extremely small, as shown by the die steep line CD.

As the temperature is raised, the horizontal portion is gradually shortened until the temperature of 31.1 °C is reached at which it reduces to a point (C). This state is referred to as the critical state of CO₂ gas.

Isotherms at 31.1°C:

In the isotherm obtained at 31.1°C, die horizontal portion vanishes and is reduced to a point. At or below 31.1°C, CPO₂ gas can be transformed into liquid by applying pressure. Thus, the liquefaction of CO₂ cannot be caused at any temperature above 31.1°C whatever the magnitude of applied pressure may be. Hence, 31.1°C is the critical temperature of CO₂.

Isotherms above 31.1°C:

P-V isotherms above 31.1°C are approximately rectangular hyperbolic. In these conditions, CO₂ gas behaves more or less as an ideal gas.

Conditions for liquefaction of gases:

Two conditions must be fulfilled for the die condensation of a gas into a liquid.

These are— die temperature of the gas must be brought equal or below the critical temperature and necessary pressure is to be applied on the gas keeping the nature ofthe gas equal or below its critical temperature.

An ideal gas cannot be liquefied due to the absence of intermolecular forces of attraction in it.

Important points related to the critical state of a gas:

Above the critical temperature, due to the very high average kinetic energy of molecules, attractions, between die molecules become negligible. As a result, it is not possible to bring the molecules closer to each other, which is necessary for the condensation of a gas.

Hence, a gaseous substance cannot be liquefied above its critical temperature even by applying very high pressure.

At the critical point, die densities of both the gaseous and liquid states of a substance become equal, and the surface of separation between these two phases disappears.

• If a substance remains above its critical temperature then the substance is called a gas. And if a substance remains below its critical temperature, then the dead substance is called a vapour.
• Thus, vapours can be liquefied only by applying pressure, but not a gas.
• To liquefy a gas, at first, the temperature ofthe gas should be brought below its critical temperature.
• The gas can then be converted into a liquid by applying the necessary pressure.
• Critical temperatures of some permanent gases such as N₂, O₂, He etc. are much lower than ordinary temperatures.
• Therefore, at ordinary temperatures, these gases cannot be liquefied by applying pressure.
• On the other hand, as the critical temperatures of gases like CO₂, CH₄ etc. are higher than ordinary temperatures, these gases can be liquefied easily at ordinary temperatures by applying pressure

The expressions of critical temperature (Tc), critical pressure (Pc) and critical volume ( Vc) for a gas obeying van der Waals equation are as follows—

⇒ \(\begin{array}{|c|c|c|}
\hline V_c=3 b & P_c=\frac{a}{27 b^2} & T_c=\frac{8 a}{27 R b} \\
\hline
\end{array}\)

∴ \(\frac{R T_c}{P_c V_c}=\frac{8}{3} \approx 2.66\)

⇒ \(\frac{R T_c}{P_c V_c}\) is called coeffiecient.

Continuity of state

We have already seen that at the critical temperature, there is no difference between the gas and the liquid phases in the P vs V diagram of CO₂ because the surface of separation between these two phases disappears at the critical temperature.

However, an isotherm at a temperature below critical temperature has a horizontal portion along which the gas and the liquid phases coexist. This indicates that the transformation of gas into liquid is a discontinuous process.

However, a close examination of an isotherm below the critical temperature reveals that it is possible to convert the gas into liquid or vice versa without any discontinuity. The phenomenon of continuous transition from gas to liquid or liquid to gas phase is called continuity of state.

The following illustrates the continuous transition from gas to liquid or liquid to gas phase. The linesEGF and ABCD indicate the respective P vs V isotherms at critical temperature (Tc) and a temperature below the critical temperature (< Tc). Any point inside the parabolic portion indicates the coexistence of gas and liquid of a substance.

On the other hand, any point outside the parabolic portion represents either the gaseous or liquid state of the substance. Initially, CO₂ is present at the gaseous state indicated by point A. The gas is then heated at constant volume till its pressure increases to a value corresponding to the point H. It is then the point H.

It is then cooled at the same pressure until its volume decreases to a value corresponding to point D. But at point D, CO₂ exists in its liquid state. Thus, gaseous CO₂ is converted into liquid CO₂ without any discontinuity because during this transition co-existence of gas and liquid phases does not occur. Hence, there exists a continuity of state during the transition from gas to liquid. The continuity of state is also found to exist during the transition from liquid to gas.

Numerical Examples

Question 1. 2 mol of a van der Waals gas at 27 °C occupies a volume of 20 L. What is the pressure of the gas? [a = 6.5 atm-L²-mol^-2; b = 0.056 L-mol^-1]
Answer:

Van der Waals equation for mol of a real gas: \(\left(P+\frac{n^2 a}{V^2}\right)(V-n b)=n R T\)

Given, n = 2 mol, V = 20L, T = (273 + 27) = 300 K, a=6.5 atm-L^-2mol^-2  and b = 0.056 L-mol^-1

∴ \(P=\frac{n R T}{V-n b}-\frac{n^2 a}{V^2}=\frac{2 \times 0.0821 \times 300}{(20-2 \times 0.056)}-\frac{(2)^2 \times 6.5}{(20)^2}
\)

= (2.477 -0.065)atm

= 2.412 atm

Question 2. A container with a volume of 5 L holds lOOg of CO at40°C. For CO₂ gas, a =3.59 L²  -atm-mol²  and b = 4.27× 10^-2  L mol^-1  . Determine the pressure of CO₂ gas. How much does this value differ from that calculated by using the ideal gas equation?
Answer:

Van der Waals equation for mol of a real gas:

⇒ \(\left(P+\frac{n^2 a}{V^2}\right)(V-n b)=n R T\)

Given, V=5L, T= (273 + 40) =313K \(n=\frac{100}{44}=2.27 \mathrm{~mol}\)

a = 3.59 L2-atm-mol-2 & b = 4.27 x 10-2 L.mol-1

∴ \(P=\frac{n R T}{V-n b}-\frac{n^2 a}{V^2}\)

⇒ \(=\frac{2.27 \times 0.0821 \times 313}{\left(5-2.27 \times 4.27 \times 10^{-2}\right)}-\frac{(2.27)^2 \times 3.59}{(5)^2}\)

=(11.9-0.74)atm = 11.16 atm

Substituting the given values of V, T and n in the ideal

gas equation PV = nRT we get,

⇒ \(P=\frac{n R T}{V}=\frac{2.27 \times 0.0821 \times 313}{5}=11.66 \mathrm{~atm}\)

∴ The pressure of CO₂ obtained from the van der Waals equation is less than that calculated from the ideal gas equation by (11.66-11.16) = 0.50 atm.

Question 3. 2 mol of gas is kept in a 4-litre flask. The pressure of the gas at 300K is 11 atm. If the value of the gas is 0.05 L-mol_1, then determine the value by using the van der Waals equation
Answer:

Van derWaals equation for’n’ mol of areal gas:

⇒ \(\left(P+\frac{n^2 a}{V^2}\right)(V-n b)=n R T\)

Given, P = 11 atm, V = 4 L, T = 300 K, n = 2 mol, b = 0.05 L.mol^-1

∴ \(\left[11+\frac{(2)^2 \times a}{(4 \mathrm{~L})^2}\right][4-2 \times 0.05]=2 \times 0.0821 \times 300\)

or, (11 + 0.25 × a)(3.9) = 49.26 or, 11 + 0.25 × a = 12.63

∴ a= 6.52 L²-atm.mol^-2

Liquid State

The liquid state is the intermediate state between the solid and gaseous states. Liquids have several properties similar to solids and gases. Like gases, liquids are isotropic. The molecules in a liquid are in continuous random motion.

So a liquid does not have a definite shape and flows like a gas. However, liquids maintain a fairly constant density like solids. Hence, liquids are incompressible like solids.

The molecules in a liquid remain ordered, somewhere between the molecular order of a solid and the molecular randomness of a gas. In liquids, the short-range ordered state extends up to a few molecular distances, whereas in solids, it extends to long-range order.

Properties Of Liquids

Shape Of A Liquid

Liquids do not have a definite shape; they take up the shape ofthe container in which they are kept.

Reason:

In liquids, the intermolecular forces of attraction are not strong enough to hold the molecules at fixed positions and thus allow them to move past one another. Hence, liquids do not have a definite shape.

Volume Of A liquid

Liquids have a definite volume. If some of the liquid is placed in a container of any shape (like a beaker, conical flask, test tube etc.), the volume of the liquid in the container will be exactly 10 mL. Like gases, liquids do not occupy the entire volume ofthe container.

Reason:

In liquids, molecules are always in motion but the movements are not as random as gas molecules. There exist stronger intermolecular forces of attraction in liquids compared to gases.

Due to this, molecules in a liquid are not widely separated from each other. Hence, liquid molecules are bound firmly but not rigidly and do not occupy the total volume ofthe container.

Density of a liquid

At ordinary temperature and pressure, the density of a liquid is much higher than that of a gas. On the other hand, the density of a substance in the liquid state is only about 10% lower than the tilting solid state.

Reason:

As the intermolecular forces of attraction are stronger in liquids than in gases the molecules are more closer to each other than the molecules in gases. This results in a little space between the molecules in liquids. This is why liquids are denser than gases.

Compressibility Of A Liquid

Liquids are much less compressible than gases. The change in the volume of liquid due to the application of pressure on it is found to be negligible.

Reason:

As the space between the molecules of liquid is very small, sufficient free space is not available for its compression. This is why the application of pressure on a liquid cannot reduce its volume appreciably.

Diffusion of a liquid

Molecules of both gases and liquids are always in random motion. Consequently, they move from one place to another. Hence, diffusion properties are shown in both gases and liquids. However, liquids diffuse very slowly compared to gases.

Reason:

As the intermolecular distances in liquids are smaller than those in gases, the molecules in a liquid suffer a large number of collisions when they move about, and hence take a longer time to move from one place to another. Hence, the diffusion of liquids occurs slowly.

Evaporation of a liquid

The gaseous state of a liquid is called its vapour. Evaporation is a process by which molecules of a liquid escape from the surface of the liquid into the gas phase. Drying of a floor after it is mopped, the gradual drying of damp clothes, the drying of water from the pond or lake in summer etc. are examples of evaporation.

Although evaporation is a slow process, some liquids have a higher rate of evaporation at ordinary temperatures. They are called volatile liquids. Ether, chloroform, carbon tetrachloride, acetone etc. These are examples of volatile liquids. On the other hand, liquids that have a very low rate of evaporation are called non-volatile liquids. Glycerol, mercury etc. are some examples of volatile liquids.

Reason for evaporation:

During evaporation, the liquid molecules at the surface of a liquid leave the liquid and go into the gaseous phase.

• The molecular interpretation of this phenomenon is as follows. Like gases, all the molecules in a liquid do not have the same kinetic energy.
• In a liquid, there is a distribution of kinetic energies of the molecules as there is a gas, A molecule at the surface of a liquid leaves the liquid when it overcomes the forces of attraction of its neighbour.
• To overcome the forces of attraction, the molecule needs to have a kinetic energy equal to or greater than a minimum kinetic energy.
• Only those molecules at the surface of the liquid will leave the liquid and go to the vapour phase, which has kinetic energies greater than or equal to the minimum kinetic energy necessary for overcoming forces of attraction.

This process in which molecules at the surface of a liquid escape and go to the vapour phase by overcoming the forces of attraction oftheir neighbours is called evaporation of liquid.

Evaporation causes cooling:

• During evaporation, only the molecules having kinetic energies greater than the characteristic kinetic energy (£) escape from the liquid surface.
• Therefore, the average kinetic energy of molecules left in the liquid decreases. As a result, the temperature of the liquid decreases.
• Thus liquid cools down during its evaporation.

Factors affecting the rate of evaporation: Factors on which the evaporation of a liquid depends are as follows:

Nature of liquid:

The rate of evaporation of a liquid depends on intermolecular forces of attraction in the liquid. This rate is slow for a liquid with a strong liquid with a weak force The strength of the intermolecular force of attraction In ethyl alcohol is weaker than that In water, but It is stronger than that in ether.

Consequently, at a given temperature, the evaporation of ethyl alcohol Is faster than that of water but slower than that of ether.

Temperature:

The rate of evaporation of a liquid Increases as temperature rises. With the temperature rise, the fraction of molecules having kinetic energy greater than characteristics kinetic energy (above which the liquid molecules can escape from the liquid surface) Increases. Therefore, the rate of evaporation increases with the temperature rise.

The surface area of the liquid:

The evaporation of a liquid occurs only from its surface. Therefore, the larger the surface area of a liquid, the greater the rate of Its evaporation.

The flow of air:

The rate of evaporation of a liquid increases when a current of air is blown across die surface of the liquid. The current of air carries away the molecules in the vapour phase of the liquid and prevents them from going back to a liquid state. This leads to faster evaporation ofthe liquid. This is why, wet clothes dry up faster when air blows rapidly.

Vapour pressure of a liquid

The evaporation of a liquid occurs from its surface at all temperatures. If a liquid is kept in a closed vessel, the vapours cannot escape from the vessel, and the vapour molecules are trapped in the space over the liquid surface.

The vapour molecules in the space of the vessel are always in random motion, so they collide with one another, with the walls ofthe container and with the liquid surface. Of the vapour molecules striking the liquid surface, those which have lower kinetic energies are recaptured by intermolecular forces of attraction in liquid.

This transfer of molecules from the vapour to the liquid phase is called condensation. Initially, the rate of condensation is slower than the rate of evaporation as the amount of vapour over a liquid surface is very small.

Gradually, the amount of vapour increases over the surface of the liquid. With increasing the amount of vapour, the rate of condensation also increases as the number of gas molecules colliding with the surface of the liquid increases.

After a certain time, the rate of evaporation and the rate of condensation become equal and an equilibrium is established between the two opposite processes, viz., evaporation and condensation. At equilibrium, the amount of liquid and that of vapour become invariant with time.

The vapour that exists over the liquid surface at equilibrium is called saturated vapour because this is the maximum amount of vapour that can be present in the space over the liquid surface at the experimental temperature. The pressure exerted by the saturated vapour is called the saturated vapour pressure or simply the vapour pressure at that experimental temperature.

Vapour Pressure

At a given temperature, the pressure exerted by a vapour in equilibrium with its liquid is called the vapour pressure of the liquid at that temperature

At a definite temperature, the vapour pressure of a liquid is always constant. Factors affecting the vapour pressure of a liquid:

Nature of the liquid:

The vapour pressure of a liquid depends on its volatility.

• The more volatile a liquid is, the higher the vapour pressure of the liquid. The volatility of a liquid depends on its rate of evaporation, which in turn depends on the intermolecular forces of attraction in the liquid.
• A volatile liquid possesses weak intermolecular attractions and has a high rate of evaporation, and hence high vapour pressure. Consequently, at a particular temperature, the vapour pressure of a volatile liquid is greater than that of a non-volatile liquid.
• The rate of evaporation of diethyl ether, ethyl alcohol and water at a definite temperature follows the sequence—diethyl ether > ethyl alcohol > water. Thus at a particular temperature, the order of their vapour pressures is—diethyl ether > ethyl alcohol > water.

Temperature:

The vapour pressure of a liquid increases with the increase in temperature. Because, with the increase in temperature, more and more liquid molecules escape into the vapour phase, thereby increasing, the amount of vapour over the liquid surface. As a result, the vapour pressure ofthe liquid increase

Boiling Of A Liquid

A liquid evaporates at any temperature. If the temperature of a liquid is increased gradually by applying heat, the rate of evaporation increases, and consequently the vapour pressure of the liquid also increases.

When the temperature of the liquid reaches a value at which the vapour pressure becomes equal to the external pressure, the bubbles of vapour are formed inside the liquid.

A very small (infinitesimal amount) increase in temperature will be sufficient for the bubbles of vapour to rise freely to the surface and escape into the air. This phenomenon is called the boiling of a liquid.

Boling Of A liquid:

Process vaporisation of a liquid is accompanied by the rapid formation and growth of bubbles of vapour that break outward through the surface of the liquid.

Boiling Point Of Liquid:

The Temperature at which the vsp[our pressure of a liquid becomes equal to the external pressure is termed as the boiling temperature or boiling of that liquid.

The normal Boiling point of a liquid:

The Temperature at which the vapour pressure of a liquid becomes equal to the normal atmospheric pressure (1 atm) is termed the normal boiling point of that liquid.

For example, the normal boiling point of water is 100°C. This means that at 100°C, the vapour pressure of water becomes equal to the atmospheric pressure. Water under atmospheric pressure (1 atm) starts boiling at this temperature.

Effect of external pressure on the boiling point of a liquid:

The boiling point of a liquid can be altered by changing external pressure. The higher the external pressure, under which a liquid exists, the higher the boiling point of the liquid.

Explanation:

The vapour pressure of a liquid becomes equal to the external pressure at its boiling point. If the external pressure is high, then it is necessary to heat a liquid at a higher temperature to make its vapour pressure equal to the external pressure so that it can start boiling.

Conversely, if the external pressure is low, then heating a liquid at a lower temperature will make its vapour pressure equal to the external pressure, thereby causing the liquid to boil.

Difference between boiling and evaporation:

Both boiling and evaporation involve the transformation of liquid into vapour. Although it would seem that evaporation and boiling might be the same process they differ in some respects.

The differences are as follows:

• Evaporation occurs only at the surface of a liquid, whereas boiling involves the formation of bubbles inside the liquid.
• Evaporation occurs slowly, whereas boiling occurs rapidly.
• Evaporation occurs at any temperature, whereas boiling occurs at a specific temperature.
• During evaporation, the temperature of liquid decreases, whereas during boiling the temperature of a liquid remains the same.

Surface Tension Of A Liquid

• Molecular interpretation of surface tension: The molecules at the surface of a liquid are energetically different from the molecules in its bulk. Let us consider a molecule, ‘A’ inside the liquid.
• The molecule ‘A’ is surrounded by other molecules and thus it is attracted equally from all sides by other molecules. So, die resultant force acting on ‘A’ is zero; that is, there is no unbalanced force acting upon’ A ‘.
• Now consider a molecule ‘ B’ at the surface of the liquid. The molecules lying below it are in liquid state and above it are in the vapour state. The molecule ‘B’ is attracted by the molecules of both liquid and vapour.
• However, as the density of vapour is much less than the density of the liquid, the number of molecules per unit volume of the liquid is much greater than that of vapour.

As a result, the molecule ‘B’ will experience a net downward force acting at right angles along the surface of the liquid.

• Similarly, other surface molecules will also be attracted towards the bulk of the liquid.
• Hence, work is to be done to bring a molecule from the bulk to the surface ofthe liquid against the downward force of attraction.
• As a result, the potential energy of the surface molecule is increased.
• Therefore, a molecule in the bulk has a lower potential energy than a molecule on the surface.
• As the energy of the surface tension of the surface tension molecule is higher, the liquid will try to minimise the energy of the surface layer (surface energy) by decreasing its surface area to a minimum.

This tendency to reduce the surface area originates the concept of a new property of liquid known as surface tension.

Due to this property, the surface of a liquid always remains under tension. This is the molecular interpretation of the surface tension of the liquid.

If we imagine a line on the surface of the liquid,l then because of the tendency of ZZ to reduce surface area, the liquid surface on one side of the line tends to move away from the liquid surface on the other side of the line. As a result, tension acts along the imaginary line from both sides. This tension is termed surface tension.

Surface Tension:

The surface tension of a liquid is defined as the force acting along the surface of the liquid at right angles to an imaginary line of unit length, drawn on the surface of the liquid.

The surface tension of a liquid is denoted by the symbol, γ (Gamma)

Units of surface tension:

Surface tension \(\frac{\text { Force }}{\text { Length }} \text {; }\) So the units of surface tension in CGS system: dyn-cm-1 ; and in SI: N-m-

The surface energy of a liquid:

The surface of a liquid always remains under a state of tension. For this reason, the surface of a liquid tends to contract to the smallest possible surface area.

Thus, it is necessary to do some work to increase the surface area against this tension. This work is ultimately stored on the surface of the liquid as potential energy. This potential energy is termed as the surface energy of a liquid.

The surface energy of a liquid Definition:

The Word Needed To Increase The Unit Area Of The Surface Of A Liquid At a Defined Temperature Is termed The Surface Energy Of That liquid.

Units of surface energy:

Surface energy \(=\frac{\text { Work }}{\text { Area }}\)

So, the unit of surface energy in the CGS system: is erg-cm-2 and in SI: J-m-2.

It can be proved that the magnitudes of surface tension and surface energy per unit area of a liquid are the same. Although the units of these two quantities are different, they are the same. The unit of surface tension in the SI system is N-m-1. In this system, the unit of surface energy is J.m^-2 But J-m^-2 = N.m.m^-2 = N-m^-1.

∴ 1 N.m^-1 = 1 J.m^-2

The unit of surface tension in the CGS system is dyn-cm^-1. In this system, the unit of surface energy is erg-cm^-2. But erg-cm^-2 – dyn-cm-cm^-2= dyncm^-1

∴ 1 dyn-cm^-1= lerg-cm^-2

Alternative Definition Of Surface Tension:

The surface tension of a liquid is defined as the amount of work necessary to increase the surface area of the liquid by a unit amount at a constant temperature.

The surface tension of water at 20°C is 7.27 × 10^-2 N-m^-1. This means, that at 20°C, 7.27 × 10^-2 work is needed to increase the surface area of water by m₂.

Surface tension of a liquid and intermolecular force of attraction:

For a liquid with strong intermolecular forces of attraction, a great deal of work is required to bring molecules from the interior to the surface i.e., in increasing the surface area of the liquid. The potential energy of the surface molecules will thus be high for such type of liquid.

The surface tension of some common liquids at 20°C

Water has a very high surface tension among the commonly known liquids. Molecules in water remain associated through hydrogen bonds:

Because of this, the intermolecular forces of attraction in water are much stronger than in any other commonly known liquids.

The surface tension of mercury is much higher than that of water:

This is because mercury possesses metallic bonds, which are much stronger than hydrogen bonds. Factors affecting the surface tension of a liquid:

Temperature:

The surface tension of a liquid decreases with the increase in temperature. The average kinetic energy of the molecules In liquid Increases with the increase in temperature, causing the weakening of its intramolecular forces of attraction.

Consequently, the surface tension of the liquid decreases. At the critical temperature, the interface between a liquid and its vapour disappears, and the surface tension of the liquid becomes zero.

Presence of soluble substance in liquid:

• The surface tension of a liquid varies according to the nature of the soluble substance present in it.
• For example, soap detergents, methanol, ethanol etc. are the surface active agents. The addition of such substances to water lowers the surface tension of water. These types of substances prefer to concentrate at the surface.
• The concentration of such a substance in its aqueous solution is found to be more at the surface than in the bulk.
• This causes the surface tension of water to decrease to an appreciable extent. The aqueous solution of soap or detergent can spread like a thin layer due to its very surface tension.

Some typical phenomena related to surface tension:

The spherical shape of the free-falling liquid drop:

• Due to the property of surface tension, the exposed liquid surface behaves like a sheet of rubber stretched on the top of a beaker and always tends to contract to the smallest possible surface area.
• Again, we know the sphere has a minimum surface area for a definite volume. So, in the absence of any external influence, a free liquid drop assumes a spherical shape.

Floating a clean oil-free needle on the surface of water:

• When a clean oil-free needle is carefully placed horizontally onto the surface of water, it is found to be floating on the surface. This happens due to the surface tension of water.
• The surface ofa liquid, due to the surface tension, always tends to be in a contracted state with a minimum space between the surface molecules. This makes the surface impervious to other molecules.
• This is why a clean oil-free needle can float on the surface of water without sinking.

A water drop spreads over the clean glass surface i.e., it can wet the surface ofthe glass. But, if a small amount of mercury is placed on the surface of a glass, it does not wet the glass surface; instead, it forms small beads:

The forces of attraction between the molecules of the same substance are called cohesive forces. The attractive forces acting between the molecules in water or mercury atoms in mercury are cohesive.

• When a substance comes in contact with another substance, the molecules of these two substances attract each other at the surface of contact. The attractive forces between the molecules of different substances are called adhesive forces.
• When water is in contact with a glass surface, the attractive forces between the molecules of water and glass are the adhesive forces. The adhesive forces between the molecules of water and glass are stronger compared to the cohesive forces in water.
• Or in glass. For this reason, a water drop spreads over the glass surface i.e., it can wet the surface of the glass. On the other hand, adhesive forces between the molecules of glass and mercury are weaker in comparison to the cohesive forces in mercury or water.
• For this reason, if mercury is placed on the surface of a glass, it forms small beads on the glass surface instead of wetting the glass.

Capillarity or capillary action:

A tube with a very small internal diameter is called a capillary tube.

• If a capillary tube is dipped into a liquid that wets glass, for example, water, the liquid rises spontaneously in the capillary tube to a certain height.
• This phenomenon is known as capillary action. Surface tension is responsible for this phenomenon.
• The surface of any liquid when kept in a container acquires a curved shape called a meniscus.
• When a capillary tube is partially immersed in a liquid-like water (that wets the glass surface), the water level inside the tube is found to be higher than that outside the tube.
• Also, the meniscus of water is concave.
• The opposite phenomenon occurs in the case of liquids (For example: mercury) that do not wet glass surfaces.

The mercury level inside the capillary tube resides at a lower level than the level outside the tube. The meniscus of mercury is of convex nature.

The forces of adhesion between the glass surface and water are stronger than the forces of cohesion in water or glass.

• To put it another way, water molecules are attracted to the glass surface more strongly than they are attracted to one another. As a result, water rises in the capillary tube and the surface becomes concave.
• On the other hand, the forces of adhesion between glass surface and mercury are weaker than the forces of cohesion in mercury or glass.
• In other words, mercury atoms are attracted to the glass surface less strongly than they are attracted to one another. As a result, the mercury surface becomes convex.

Viscosity of a liquid

If a liquid flows in such a manner that its velocity at any point always remains constant in magnitude and direction, then the flow is called streamline flow. Streamline flow generally occurs when the velocity of a liquid is low.

• When a liquid flows slowly and steadily along a tube i.e., when the flow is streamlined, the liquid can be considered to be made up of stratified layers.
• Among the layers, the layer ofthe liquid in immediate contact with the surface is stationary due to adhesion. The highest velocities are observed in the middle of the tube along its axis. The velocity diminishes as we approach the walls.
• Now, consider two adjacent layers B and C. The layer C is moving with a higher velocity than the layer B because the former is above the latter.
• Because of its higher velocity, layer C tends to increase the velocity of the adjacent lower layer B. Similarly, the slower-moving layer B tends to decrease the velocity of the adjacent upper layer C.

These two layers thus tend to destroy their relative emotions. This means that a dragging force acts on the layers in the backward direction. This force is called viscous force, which arises due to cohesion. The viscous force has a similarity with the frictional force so it is also often called the force of internal friction.

Viscous force resists the flow of a liquid and ultimately stops it. An equal and opposite force ofthe viscous force is to be applied to maintain the flow of the liquid with a constant velocity. If the liquid remains stagnant then viscous force does not act upon it.

Viscosity:

• The viscosity of a liquid is the property of the liquid that resists the flow of the liquid. It is a measure of the ease with which a liquid flows.
• Different liquids have different values of viscosity. The higher the viscosity of a liquid, the lower its tendency to flow. For example, the viscosities of liquids like glycerin, honey, castor oil etc. are high, and hence their flow rates are low.
• On the other hand, the lower the viscosity of a liquid, the higher its tendency to flow. For example, the viscosities of liquids like water, alcohol, ether etc. are low, resulting in high flow rates of these liquids.

Coefficient of viscosity:

Consider a liquid which is flowing steadily and slowly over a flat horizontal surface (streamline flow). The layer just next to the solid surface is at rest due to adhesion.

• With increasing the distances of the layers from the solid surface, the velocities of the layers also increase.
• Let us consider, two layers C and D having velocities v and v + dv, respectively. The distances of these two layers

from the solid surface are x and x + dx respectively.  So, the velocity gradient i.e., the rate of change in velocity along the x-axis (axis perpendicular to the flow of liquid) is

⇒  \(\left(\frac{d v}{d x}\right)\) direction opposite to the direction of flow. To maintain the flow, an equal and opposite force to the viscous force is to be applied from outside.

According to Newton’s law of viscous flow, the value of the viscous force (F) is proportional to O the area of the surface in contact (A) and the velocity gradient

⇒ \(\left(\frac{d v}{d x}\right)\)

Therefore \(F \propto A \text { and } F \propto \frac{d v}{d x}\)

∴ \(F \propto A \frac{d v}{d x} \text { or, } F=\eta \times A \times \frac{d v}{d x}\)

Where n (eta) is the proportionality constant called the viscosity coefficient. The value of TJ depends upon the temperature and nature of the liquid.

If A =1 and \(\frac{d v}{d x}=1\) Then according to equation F=n

Viscosity Coefficient: It is the tangential force applied per unit area to maintain a unit velocity gradient between two parallel layers at a constant temperature

Liquids with high viscosity have high values of viscosity coefficients (for example, glycerin, oil, honey etc.). Similarly, liquids with low viscosity have low viscosity coefficients (for example, water, alcohol etc.)

Units of viscosity coefficient:

In the CGS system:

The CGS unit of viscosity coefficient is poise (after the name of the French scientist Poiseuille). From equation [1], we get,

⇒ \(\eta=\frac{F}{A \times \frac{d v}{d x}}=\frac{\text { dyn }}{\mathrm{cm}^2 \times \frac{\mathrm{cm} \cdot \mathrm{s}^{-1}}{\mathrm{~cm}}}=\text { dyn } \cdot \mathrm{s} \cdot \mathrm{cm}^{-2}\)

1 poise =1 dyn.s.cm^-2

Poise:

The force in dyne required per 1cm₂ area to maintain a velocity difference of 1 cm.s^-1 between two parallel layers of a liquid, separated by 1 cm is called 1 poise.

The viscosity coefficients are also expressed in some smaller units like centipoise, millipoise, micropoise etc.

1 centipoise = 10^-2 poise,1 millipore = 10-3 poise, 1 microphone = 10^-6poise

In the SI system:

The SI unit of viscosity coefficient is poiseuille (PI) From equation [1] we get

⇒ \(\eta=\frac{F}{A \times \frac{d v}{d x}}=\frac{\mathrm{N}}{\mathrm{m}^2 \times \frac{\mathrm{m} \cdot \mathrm{s}^{-1}}{\mathrm{~m}}}=\mathrm{N} \cdot \mathrm{s} \cdot \mathrm{m}^{-2}=\mathrm{Pa} \cdot \mathrm{s}\)

Since 1 N-m^-2 = 1 Pa

Since 1 poiseuille or 1 PI =1 N s m^-2 = 1 Pa s

1 poise = lady-s-cm^-2 = 10^-5N-s × (10^-2m)^-2

= 0.1 N-s-m^-2 = 0.1 PI

∴ 1 PI = 10 poise

Factors that influence the viscosity of a liquid:

Intermolecular forces of attraction in a liquid:

Viscosity is the property of a liquid that originates from its intermolecular forces of attraction. The stronger the intermolecular forces of attraction, the higher the viscosity of a liquid.

Example:

At a constant temperature, the viscosity coefficient of ethyl alcohol is greater than that of dimethyl ether. In dimethyl ether, molecules experience dipole-dipole attractive forces in addition to London forces.

In ethanol, molecules form hydrogen bonds. London forces also exist between the molecules in ethanol.

Attractive forces due to hydrogen bonding are much stronger than dipole-dipole attractive forces. So, intermolecular forces of attraction are stronger in ethanol than those in dimethyl ether. This results in a higher value of coefficient of viscosity for ethanol compared to dimethyl ether.

Temperature:

With the increase in temperature, the average kinetic energy of the molecules in a liquid increases, this causes the weakening of its intermolecular forces of attraction which are responsible for the viscosity of the liquid.

For this reason, the viscosity of a liquid decreases with the increase in temperature. Experimentally, it has been found that the viscosity of a liquid decreases approximately by 2% for a 1° rise in temperature.

States Of Matter Gases And Liquids Numerical Examples

Question 1. At 10-3 mm pressure and 300K, a 2L flask contains equal numbers of moles of N₂ and water vapour, What is the total number of moles of N₂ and water vapour in the mixture? What is the total mass ofthe mixture?
Answer:

⇒  \(n=\frac{P V}{R T}=\frac{\left(10^{-3} / 760\right) \times 2}{0.0821 \times 300}=1.06 \times 10^{-7} \mathrm{~mol}\)

⇒ \(n_{\mathrm{N}_2}=n_{\mathrm{H}_2 \mathrm{O}}=\frac{n}{2}=\frac{1.06 \times 10^{-7}}{2}=5.3 \times 10^{-8} \mathrm{~mol}\)

∴ Total Mass \(m_{\mathrm{N}_2}+m_{\mathrm{H}_2 \mathrm{O}}\)

⇒ \(=\left(5.3 \times 10^{-8} \times 28+5.3 \times 10^{-8} \times 18\right) \mathrm{g}=2.44 \times 10^{-6} \mathrm{~g}\)

Question 2. At constant temperature and 1 atm pressure, an ideal gas occupies a volume of 3.25m₃. Calculate the final pressure of the gas in the units of atm, torr and Pa if its volume is reduced to 1.25m₂ while its temperature is kept constant.
Answer:

⇒ \(P_2=\frac{P_1 V_1}{V_2}=\frac{1 \times 3.25}{1.25}=2.6 \mathrm{~atm}\)

= \(2.6 \times 760 \mathrm{torr}=1.976 \times 10^3 \mathrm{torr}=2.633 \times 10^5 \mathrm{~Pa}\)

Question 3. The density of a gas at 27°C and 1 atm is 15g-mL-1.At what temperature, will the density of that gas be 10g-mL-1, at the same pressure?
Answer:

⇒ \(\frac{d_2}{d_1}=\frac{T_1}{T_2} \text { or, } T_2\)

= \(\frac{d_1}{d_2} \times T_1=\frac{15}{10} \times 300=450 \mathrm{~K} \text {; }\)

∴ t= 177°C

Question 4. The density of a gas at 30°C and 1.3 atm pressure is 0.027 g- mL-1. What is the molar mass ofthe gas?
Answer:

⇒ \(d=\frac{P M}{R T} \text { or, } M=\frac{d R T}{P}\)

=\(\frac{0.027 \times 0.0821 \times 10^3 \times 303}{1.3}\)

= \(516.6 \mathrm{~g} \cdot \mathrm{mol}^{-1}\)

Question 5. 0.0286 g of a gas at 25°C and 76 cm pressure occupies a volume of 50 cm³. What is the molar mass of the gas?
Answer:

M = \(\frac{g R T}{P V}=\frac{0.0286 \times 0.0821 \times 298}{1 \times 50 \times 10^{-3}}\)

= \( 14 \mathrm{~g} \cdot \mathrm{mol}^{-1}\)

Question 6. The density of a gas at -135°C and 50.66 atm pressure is 2g- cm-3. What is the density ofthe gas at STP?
Answer:

⇒ \(\frac{d_2}{d_1}=\left(\frac{P_2}{P_1}\right) \times\left(\frac{T_1}{T_2}\right)\)

⇒ \(\text { or, } d_2=2 \times \frac{1}{50.66} \times \frac{138}{273}=0.02 \mathrm{~g} \cdot \mathrm{cm}^{-3}\)

Question 7. A gaseous mixture contains 336 cm₃ of H₂ and 224 cm₃ of HE at STP. The mixture shows a pressure of 2 atm when it is kept in a container at 27°C. Calculate the volume of the gas.
Answer:

⇒\(\text { At STP, } 336 \mathrm{~cm}^3 \text { of } \mathrm{H}_2 \equiv \frac{336}{22400} \equiv 0.015 \mathrm{~mol} \text { of } \mathrm{H}_2 \text { and }\)

⇒ \(224 \mathrm{~cm}^3 \text { of } \mathrm{He} \equiv \frac{224}{22400} \equiv 0.01 \mathrm{~mol} \text { of } \mathrm{He} \text {. }\)

⇒ \(V=\frac{n R T}{P}=(0.015+0.01) \times \frac{0.0821 \times 300}{2}=307.8 \mathrm{~cm}^3\)

Question 8. At 100°C a 2-litre flask contains 0.4 g of O₂ and 0.6 g of H₂. What is the total pressure of this gas mixture in the flask?
Answer:

⇒ \(P=\frac{n R T}{V}=\frac{\left(\frac{0.4}{32}+\frac{0.6}{2}\right) \times 0.0821 \times 373}{2}=4.78 \mathrm{~atm}\)

Question 9. 1.0 g of benzene is burnt completely in the presence of 4.0 g O₂ in a completely evacuated bomb calorimeter of volume 1L. What is the pressure inside the bomb at 30°C, if the volume and pressure of water vapour produced are neglected?
Answer:

lg of benzene \(=\frac{1}{78}\) 0.0128 mol of benzene

⇒ \(4 \mathrm{~g} \text { of } \mathrm{O}_2\)

=\(\frac{4}{32}=0.125 \mathrm{~mol} \text { of } \mathrm{O}_2\)

⇒ \(\mathrm{C}_6 \mathrm{H}_6(l)+\frac{15}{2} \mathrm{O}_2(g) \longrightarrow 6 \mathrm{CO}_2(g)+3 \mathrm{H}_2 \mathrm{O}(g) 0.0128 \mathrm{~mol} \frac{15}{2} \times 0.0128 6 \times 0.0128\)

= \(0.096 \mathrm{~mol}=0.0768 \mathrm{~mol}\)

Total number of moles of CO₂ produced and O₂ remained = (0.0768 + (0.125- 0.096)

⇒ \(P=\frac{n R T}{V}=\frac{0.1058 \times 0.0821 \times 303}{1}=2.63 \mathrm{~atm}\)

Question 10. A closed vessel of fixed volume is filled with 3.2 g O₂ at a pressure of P atm and a temperature of T_k. The containers were then heated to a temperature of (T+ 30)K. To maintain the pressure of P atm inside the container at (T+30)K, a certain amount of gas is removed from the container. The gas removed is found to have a volume of 246mL at atm and 27°C. Calculate T.
Answer:

Suppose the number of moles Of O₂ removed = n1 mol

∴ \(n_1=\frac{P V}{R T}=\frac{1 \times 246 \times 10^{-3}}{0.0821 \times 300}=9.98 \times 10^{-3} \mathrm{~mol}\)

The number of moles of oxygen that remained in the container

⇒ \(\left(n_2\right)=\left(\frac{3.2}{32}-9.98 \times 10^{-3}\right)\mathrm{mol}=0.09 \mathrm{~mol}\)

Initial state: PV = NRT \(=\frac{3.2}{32} R T=0.1 R T\)

Final state: PV = n₂RT = 0.09 X R(T+ 30)

∴ 0.17TT = 0.09 x R(T+ 30); hence, T = 270K

Question 11. The temperature of an ideal gas is 340K. The gas is heated to a temperature at constant pressure. As a result, its volume increases by 18%. What is the final temperature of the gas?
Answer:

⇒ \(\frac{V_2}{V_1}=\frac{T_2}{T_1} \text { or, } \frac{(1.18) V_1}{V_1}=\frac{T_2}{340} ; \text { hence, } T_2=401.2 \mathrm{~K}\)

Question 12. What is the density of air at STP? Assume that air contains 78% N2 and 22% O₂ by masses.
Answer:

Average molar masses are –

⇒ \(\frac{28 \times 78+32 \times 22}{100}=28.88 \mathrm{~g} \cdot \mathrm{mol}^{-1}\)

d= \(\frac{P M}{R T}=\frac{1 \times 28.88}{0.0821 \times 273} \mathrm{~g} \cdot \mathrm{L}^{-1}=1.288 \mathrm{~g} \cdot \mathrm{L}^{-1}\)

Question 13. At 100°C and 1 atm pressure, the densities of water and water vapour are 1.0 g-mL-1 and 0.0006 g-mL-1 respectively. What is the total volume of water molecules in a litre of steam at 100°C?
Answer:

Mass of1L of steam = 1000 × 0.0006 g = 0.6 g

Amount of water in 1L of steam = 0.6 g

The volume of water in 1 L of steam

Question 14. The volume of 0.44 g of a colourless oxide of N₂ is 224 mL at 273°C and 1530 mm pressure. What is the compound?
Answer:

PV = \(\frac{g}{M} R T\)

Or,M =\(\frac{g R T}{P V}\)

= \(=\frac{0.44 \times 0.0821 \times 546}{\left(\frac{1530}{760}\right) \times 224 \times 10^{-3}}\) 44g.mol^-1

The expected compound is N₂O.

Question 15. A spherical balloon is filled with air at 2 atm pressure. What pressure is to be exerted on the balloon from the outside so that its diameter will be reduced to half of its initial diameter?
Answer:

⇒ \(\text { Initial state, } 2 \times \frac{4}{3} \pi r^3=n R T \text {; }\)

⇒ \(\text { Final state: } P \times \frac{4}{3} \pi\left(\frac{r}{2}\right)^3=n R T[r=\text { radius of the balloon }]\)

∴ \(P V=n R T ; P \times \frac{1}{8}=2 \text { or, } P=16 \text { atm }\)

Question 16. If 3.2 g of sulphur is heated to a temperature, the sulphur vapour produced occupies a volume of 780 mL at 723 mm pressure and 450°C. What is the molecular formula of sulphur at this state?
Answer:

Let the molecular formula of sulphur is S_X.

∴ \(3.2 \mathrm{~g} \text { of sulphur }=\frac{3.2}{32 \times x}=\frac{1}{10 x} \mathrm{~mol} \text { of sulphur }\)

PV=nRT

⇒ \(\text { or, } \frac{723}{760} \times 780 \times 10^{-3}=\frac{1}{10 \times x} \times 0.0821 \times(450+273)\)

∴ The molecular formula of sulphur = Sb.

Question 17. Determine partial pressures of O₂ and N₂ in air at 0°C and 760 mm Hg pressure. Air contains 78% N₂ and 22% O₂ by volume.
Answer:

Mole fraction of

⇒  \(\mathrm{N}_2\left(x_{\mathrm{N}_2}\right)=\frac{\text { Partial volume of } \mathrm{N}_2}{\text { Total volume }}=\frac{78}{100}\)

= 0.78

Similarly, mole-fraction of  O₂(XO₂ ) \(\frac{22}{100}=0.22\)

PN₂ = XN₂ × P = 0.78  ×  760mm

Hg = 592.8 mm Hg

PO₂ = XO₂ ×  P = 0.22 ×760mm

Hg = 167.2 mm Hg

Question 18. 200 cm₃ of N₂ gas is collected over water at 20°C and 730 mm pressure. At this temperature, aqueous tension is 14.20 mm. What is the mass of N₂ gas collected?
Answer:

PO₂  = (730- 14.200mm Hg

Hg = 0.9418 atm

⇒  \( p_{\mathrm{N}_2} \times V_{\mathrm{N}_2} \)

= \(n R T \text { or, } 0.9418 \times 0.2=\frac{w}{28} \times 0.0821 \times 293\)

∴ w = 0.219 g

Question 19. 0.5 g O₂ gas is collected over water at 20°C and 730 mm pressure. If aqueous tension at that temperature is 14.20 mm, what is the volume of O₂ gas collected?
Answer:

⇒  \(p_{\mathrm{O}_2}=(730-14.20) \mathrm{mm} \mathrm{Hg}=0.9418 \mathrm{~atm}\)

⇒\(p_{\mathrm{O}_2} \times V_{\mathrm{O}_2}=n R T\)

Or, \(0.9418 \times V_{\mathrm{O}_2}\)

= \(\frac{0.5}{32} \times 0.0821 \times 293\)

∴ \(V_{\mathrm{O}_2}=0.399 \mathrm{~L}\)

= 399cc

Question 20. A vessel contains equal masses of CH₄ and H₂ gas at 25°C. What part of the total pressure inside the vessel is equal to the partial pressure of H₂ gas?
Answer:⇒ 

⇒  \(W_{\mathrm{CH}_4}=W_{\mathrm{H}_2}=W ;\)

∴ \(n_{\mathrm{CH}_4}=\frac{W}{16} \mathrm{~mol} \text { and } n_{\mathrm{H}_2}=\frac{W}{2} \mathrm{~mol}\)

⇒ \(\text { Total mol, } n=\left(\frac{W}{16}+\frac{W}{2}\right) \mathrm{mol}=\frac{9 W}{16} \mathrm{~mol}\)

Question 21. 8g O₂ and some quantity of CO₂ are introduced at 30°C into an empty flask of volume 10L. If the total pressure of the gas, the mixture in the flask is 1520 mm. Find the amount of CO₂ gas taken.
Answer:

⇒ \(P V=n R T \text { or, } \frac{1520}{760} \times 10=\left(\frac{8}{32}+\frac{W}{44}\right) \times 0.0821 \times 300\)

∴ W= 24.72 g

Question 22. Partial pressures of the component gases in a gas mixture are H₂ = 300 mm; CH₄ – 150 mm; N₂ = 250 mm. What is the percentage of N₂ gas by volume in the mixture?
Answer:

⇒ \(x_{\mathrm{N}_2}=\frac{\text { Partial volume of } \mathrm{N}_2}{\text { Total pressure }}=\frac{250}{300+150+250}=0.3571\)

The volume per cent of N₂ in the mixture = Mole-fraction of N₂ in the mixture ×100

= 35.71%

Question 23. At constant temperature, 2L of N₂ gas at 750 mm Hg pressure is mixed with 3L of O₂ gas. As a result, the pressure and volume ofthe gas mixture are found to be 732 mm Hg and 5L respectively. What is the initial pressure of O₂ gas?
Answer:

⇒ \(P_{\mathrm{N}_2} \times V=n_{\mathrm{N}_2} R T\) : \(\mathrm{P}_{\mathrm{O}_2} \times V=n_{\mathrm{O}_2} R T\)

⇒ \(750 \times 2=n_{\mathrm{N}_2} R T\) : \(P_{\mathrm{O}_2} \times 3=n_{\mathrm{O}_2} R T\)

In mixture:

⇒ \(P V=n R T=\left(n_{\mathrm{O}_2}+n_{\mathrm{N}_2}\right) R T=P_{\mathrm{O}_2} \times 3+750 \times 2\)

⇒ \(732 \times 5=P_{\mathrm{O}_2} \times 3+1500\)

∴ \(P_{\mathrm{O}_2}=720 \mathrm{~mm} \mathrm{Hg}\)

Question 24. The respective mole fractions of N₂ and O₂ in dry air are 0.78 and 0.21. If the atmospheric pressure and temperature are 740 torr and 20°C respectively, then what will be the mass of N₂ and O₂ present in a room of volume 3000ft₃? (Assuming the relative humidity of the air as zero)
Answer:

⇒ \(p_{\mathrm{N}_2}=0.78 \times 740 \text { torr }=0.78 \times \frac{740}{760}=0.76 \mathrm{~atm}\)

3000 ft³ = 3000 ×  (30.48)3 [since ft = 30.48 cm]

= 84.95 ×106 cc = 84.95 × 103L

∴ PN₂ × V= n_N2 ×RT

or, 0.76 × 84.95 × 10³ = N × 0.0821 × (273 + 20)

Or, n_N2= 2.683 × 10³ mol

∴ Mass of N₂ = 2.683×10³ × 28g = 75.149 kg In calculation, it can be shown that mass of O₂ = 23.107 kg

Question 25. 300 cm₃ of H₂ gas diffuses through a fine orifice in 1 minute. At the same temperature and pressure, what volume of CO₂ gas will diffuse through the same orifice in 1 minute?
Answer:

⇒ \(\frac{V_{\mathrm{H}_2}}{V_{\mathrm{CO}_2}}=\sqrt{\frac{M_{\mathrm{CO}_2}}{M_{\mathrm{H}_2}}}=\sqrt{\frac{44}{2}}\)

⇒ \(\text { or, } V_{\mathrm{CO}_2}=\frac{1}{\sqrt{22}} \times 300 \mathrm{~cm}^3=63.96 \mathrm{~cm}^3\)

Question 26. At constant temperature and pressure, the rates of diffusion of two gases A and B are in the ratio of 1: 2. In a mixture of A and B gases mass ratio of A and B is 2:1, so find the mole fraction ratio of A and B in the mixture.
Answer:

⇒ \(\frac{r_A}{r_B}=\sqrt{\frac{M_B}{M_A}} \text { or, } \frac{1}{2}=\sqrt{\frac{M_B}{M_A}} \text { or, } M_A=4 M_B\)

⇒ \(\frac{\mathrm{W}_A}{\mathrm{~W}_B}=2 \text { or, } \frac{n_A \times M_A}{n_B \times M_B}=2 \text { or, } \frac{n_A}{n_B}=\frac{1}{2} \text {; }\)

∴ \(\frac{x_A}{x_B}=\frac{n_A}{n_B}=\frac{1}{2}\)

Question 27. The average velocity of the molecules of a gas is 400m- s-1. At the same temperature, what will be the rms velocity of the molecules?
Answer:

⇒ \(c_a=\sqrt{\frac{8 R T}{\pi M}} \quad c_{r m s}=\sqrt{\frac{3 R T}{M}}\)

∴ \(c_a=\sqrt{\frac{8}{3 \pi}} \times c_{r m s}\)

⇒ \(\text { or, } c_{r m s}=\sqrt{\frac{3 \pi}{8}} \times 400=434.05 \mathrm{~m} \cdot \mathrm{s}^{-1}\)

Question 28. At a constant temperature and 1 atm pressure, the density of O₂ gas is 0.0081 g- mL-1. At the same temperature, calculate the average velocity, root mean square velocity and most probable velocity of O₂ molecules.
Answer:

⇒ \(c_{r m s}=\sqrt{\frac{3 P}{d}}=\sqrt{\frac{3 \times 76 \times 13.6 \times .981}{0.0081}}=1.937 \times 10^4 \mathrm{~cm} / \mathrm{s}\)

⇒ \(c_a=\sqrt{\frac{8}{3 \pi}} c_{r m s}\)

= \(\sqrt{\frac{8}{3 \pi}} \times 1.937 \times 10^4 \mathrm{~cm} / \mathrm{s}\)

= \( 1.785 \times 10^4 \mathrm{~cm} / \mathrm{s}\)

⇒ \(c_m=\sqrt{\frac{2 R T}{M}}=\sqrt{\frac{2}{3}} \times \sqrt{\frac{3 R T}{M}}=\sqrt{\frac{2}{3}} \times c_{r m s}\)

⇒ \(\sqrt{\frac{2}{3}} \times 1.937 \times 10^4 \mathrm{~cm} / \mathrm{s}=1.581 \times 10^4 \mathrm{~cm} / \mathrm{s}\)

Question 29. A certain gas of mass 6.431 g occupies a volume of 5 L at a definite temperature and 750 mm pressure. At the temperature, what will be the rms velocity of the molecules of that gas?
Answer:

⇒ \(P V=n R T=\frac{W}{M} R T \text { or, } \frac{R T}{M}=\frac{P V}{\mathrm{~W}}=\frac{750}{760} \times 5 \times \frac{1}{6.431} \mathrm{~g}^{-1}\)

= 0.7672 L-atm.g-1

= 0.7672 ×10³ ×  1.013 × 106 cm 2.s^-2

[since 1 atm = 1.013 × 10⁶g-cm-1-s^-2]

∴ \(c_{r m s}=\sqrt{\frac{3 R T}{M}}=\sqrt{3 \times 0.7672 \times 1.013 \times 10^9} \mathrm{~cm} / \mathrm{s}\)

Question 30. What is the ratio of average velocity and root mean square velocity ofthe molecules of a gas?
Answer:

⇒ \(c_e=\sqrt{\frac{B R T}{\pi M}}, c_{m m}=\sqrt{\frac{3 R T}{M}}\)

∴ \(\frac{c_a}{c_{m s}}=\sqrt{\frac{8}{3 \pi}}=0.9215\)

Question 31. At what temperature will the rms velocity of S02 molecules be equal to the rms velocity of O₂ molecules at 25°C?
Answer:

⇒  \(c_{\mathrm{rm}}\left(\mathrm{SO}_2\right)=\sqrt{\frac{3 R T}{64}}, c_{\mathrm{mav}}\left(\mathrm{O}_2, 25^{\circ} \mathrm{C}\right)=\sqrt{\frac{3 R \times 298}{32}}\)

∴ 7= 596K ie.,t = 323

=C

Question 32. Show that the rms velocity of O₂ molecules at 50°C is not equal to the rms velocity of N₂ molecules at 25°C.
Answer:

⇒ \(c_{\mathrm{rms}}\left(\mathrm{O}_2\right)=\sqrt{\frac{3 R \times(273+50)}{32}}\)

⇒  \(c_{r m s}\left(\mathrm{~N}_2\right)=\sqrt{\frac{3 R \times(273 \div 25)}{28}}\)

∴ \(c_{\mathrm{ms}}\left(\mathrm{O}_2 \text { at } 50^{\circ} \mathrm{C}\right)=c_{\mathrm{ms}}\left(\mathrm{N}_2 \text { at } 25^{\circ} \mathrm{C}\right)\)

Question 33. The average kinetic energy of the atom of Hg vapour is 1000 cal-mol-1. What will be the value of its rms velocity? [Hg = 200]
Answer:

E =  \(\frac{3}{2} R T\)

=\(1000 \mathrm{cal} \cdot \mathrm{mol}^{-1}\)

=\(1000 \times 4.157 \times 10^7 \mathrm{erg} \cdot \mathrm{mol}^{-1}\)

∴ 3RT = 2000 × 4.157 ×10⁷g.cm².s^-2.mol^-1

ns =  \(\sqrt{\frac{3 R T}{M}}=\sqrt{\frac{2000 \times 4.157 \times 10^7}{200}} \mathrm{~cm} / \mathrm{s}\)

=2.04 × 10⁴ cm/s

Question 34. In a container of volume 1L, there are 10²³ gas molecules, each of which has a mass of 10^-22g. At a certain temperature, if the rms velocity of these molecules is 105cm.s^-1, then what would be the pressure at the temperature inside the container?
Answer:

P V = \(\frac{1}{3} m n c_{r m s}^2\)

Or, \(P \times 1000\)

=\(\frac{1}{3} \times 10^{-22} \times 10^{23} \times\left(10^5\right)^2\)

∴ P = 3.33× 10¹⁰ g.cm^-1.s²

= 3.33 × 10¹⁰ dyne = 32.87 atm

Question 35. At a constant temperature, a vessel of 1-litre capacity contains 1023 N₂ molecules. If the rms velocity of the molecules is 10³m/s, then determine the total kinetic energy of the molecules and the temperature ofthe gas.
Answer:

Average kinetic energy per molecule

⇒ \(\frac{1}{2} m c_{r m s}^2=\frac{1}{2} \times \frac{28}{6.023 \times 10^{23}} \times\left(10^3\right)^2 \mathrm{~g} \cdot \mathrm{m}^2 \cdot \mathrm{s}^{-2}\)

= 2.324 × 10¹⁷g-m²-s^-2

= 2.324 × 10²⁰ J

Average kinetic energy per molecule \(=\frac{3}{2} k T\)

⇒ \(\text { or, } \frac{3}{2} \times \frac{8.314}{6.023 \times 10^{23}} \times T=2.324 \times 10^{-20} ; T=1122.6 \mathrm{~K}\)

Total kinetic energy of 10²³ molecules

Question 36. At 0°C the kinetic energy of 10₂ molecules is 5.62 x 10-14 erg. Determine Avogadro’s number.
Answer:

⇒  \(\bar{\epsilon}=\frac{3}{2} K T=\frac{3}{2} \times \frac{R}{N_A} \times T\)

⇒ \(\text { or, } 5.62 \times 10^{-14}=\frac{3}{2} \times \frac{8.314 \times 10^7}{N_A} \times 273 \text {; }\)

∴ NA= 6.058 ×10²³

Question 37. The volume of 2 moles of SO₂ at 30°C and 55 atm pressure is 680 mL. What is the value of the compressibility factor of the gas? What is the nature of the deviation of the gas from ideal behaviour?
Answer:

⇒   \(Z=\frac{P V}{n R T}=\frac{55 \times 680 \times 10^{-3}}{2 \times 0.0821 \times 303}\)

= 0.7517

As Z < 1, the gas shows a negative deviation from ideal behaviour.

Question 38. The compressibility factor of a real gas at 0°C and 100 atm pressure is 0.927. At this temperature and pressure, how much of this real gas is required to fill a vessel of 100L [molar mass =40g-mol-1?
Answer:

⇒ \(Z=\frac{P V}{n R T} \text { or, } 0.927=\frac{100 \times 100}{n \times 0.0821 \times 273}\)

∴ n = 481.298mol

∴ Amount of gas required =481.298 × 40g = 19.2519kg

Question 39. For a van der Waals gas, b = 5.0 x 10-2 L-mol-1. What is the diameter of a molecule of this gas?
Answer:

⇒ \(b=4 N_A \times \frac{4}{3} \pi r^3\)

⇒ \(5 \times 10^{-2} \times 1000 \mathrm{~cm}^3 \cdot \mathrm{mol}^{-1}\)

= \(4 \times 6.023 \times 10^{23} \times \frac{4}{3} \pi r^3\)

r = \(1.705 \times 10^{-8} \mathrm{~cm}\)

∴ Diameter of a molecule = 3.41 × 10^-8 cm

Question 40. The volume of 2 moles of CO₂ gas at 27°C is 0.001 m3. What will be the pressure of this gas According to the van der Waals equation and ideal gas equation? [Given a(CO₂ ) =0.364 N.m⁴.mol^-2 and b(CO₂) = 4.27 × 10^-5 m^3.mol^-1 ]
Answer:

1.   \(\left(P+\frac{n^2 a}{V^2}\right)(V-n \dot{b})=n R T\)

Or,\(\text { or, }\left(P+\frac{2^2 \times 0.364 \mathrm{~N} \cdot \mathrm{m}^4}{10^{-6} \mathrm{~m}^6}\right)\left(10^{-3}-2 \times 4.27 \times 10^{-5}\right) \mathrm{m}^3\)

= 2 × 0.0821 × 300 L-atm

Or, (P + 1.456 × 106N-m^-2)(9.146 ×10 m³)

= 2 × 0.0821 × 300 × 10^-3 m³-atm

or, P+ 1.456 ×  10⁶ ×  10^-5atm = 53.859 atm

P = 39.299 atm

2. PV = nRT

Or, P = \(\frac{2 \times 0.0821 \times 300}{0.001 \mathrm{~m}^3} \mathrm{~L} \cdot \mathrm{atm}\)

= \(49260 \frac{\mathrm{L} \cdot \mathrm{atm}}{\mathrm{m}^3}=\)

=49.26 atm

Question 41. The equation of state for 1 the mole of a gas is (V-b) = RT. At STP, 1 mole of this gas occupies a volume of 28L. Calculate the compressibility factor ofthe gas at STP.
Answer:

Z= \(\frac{P V}{n R T}=\frac{1 \times 28}{1 \times 0.0821 \times 273}=1.249\)

Question 42. The compressibility factor of 2 mol of NH₃ gas at 27°C and 9.18 atm pressure is 0.931. If the volume of the gas molecules is not taken into consideration, then what is the value of van der Waals constant ‘a’ for NH₃ gas?
Answer:

⇒ \(\left(P+\frac{n^2 a}{V^2}\right) V=n R T \text { or, } P V=n R T-\frac{n^2 a}{V}\)

⇒ \(\text { or, } \frac{P V}{n R T}=1-\frac{n a}{V R T} \text { or, } Z=1-\frac{n a}{V R T}=1-\frac{2 \times a}{V R T}\)

⇒ \(\text { again, } \quad Z=\frac{P V}{n R T} \quad \text { or, } \quad 0.931=\frac{9.18 \times V}{2 \times 0.0821 \times 300}\)

∴ V= 4.991

∴ 0.931 \(=1-\frac{2 \times a}{4.99 \times 0.0821 \times 300}\)

a= 4.2412.atm.mol¯²

Question 43. The pressure exerted by 12g of an ideal gas at t°C in a vessel of volume VL is late. When the temperature is increased by 10°C at the same volume, the pressure increases by 10%. Calculate the temperature ‘f and volume V (molar mass of gas = 120).
Answer:

⇒ \(12 \mathrm{~g} \text { of the gas }=\frac{12}{120}=0.1 \mathrm{~mol} \text { of the gas }\)

Given that the initial pressure of the gas, P = 1 atm and its initial temperature, T = (273 + t)K

By applying ideal gas equation, PV= nRT, we get 1×V = 1 × 0.0821 × (273 + t)………………….(1)

It is given, the final pressure of the gas, \(P=\left(1+\frac{10}{100} \times 1\right)\)

1.1 atm

and its final temperature = (273 + 1 + 10)K = (283+)K

By applying the gas equation, PV = nRT, we get

1.1 × V = 1 × 0.0821 × (283 + t) ………………….(2)

From the equations (1) and (2), we have

1.1 × 0.0821 × (273)+= 1 × 0.0821 × (283 + t)

or, 1.1(273 + t) = 283 + t

∴ t = -173; So, the value off = -173°C

Putting t = -173 in equation [1] (or in equation (2),

We have, V = 1 × 0.0821(273-173) = 0.821L

Question 44. An open vessel contains air at 27°C. At what temperature should the vessel be heated so that l/4th of air escapes from the vessel? Assume that volume ofthe vessel remains the same on heating.
Answer:

Initial temperature of air = (273 + 27)K = 300K.

Let the amount of air in the vessel at 27°C = x mol.

Suppose, the vessel is heated to a temperature of T₁K so that 1 /4 th of air escapes from the vessel.

So, the amount of air in the vessel at,\(T_1 K=x-\frac{x}{4}=\frac{3}{4} x\)

Since the vessel is open, the pressure of air in the vessel either at 300K or at TK is equal to atmospheric pressure, i.e., 1 atm.

Again, the volume of the vessel does not change because of heating. Therefore, at temperature 300K.

⇒ \(x \times 0.0821 \times 300=\frac{3}{4} x \times 0.0821 \times T_1 \text { or, } T_1=400 \mathrm{~K}\)

Question 45. A container of fixed volume 0.4L contains 0.56g of gas at 27°C. The pressure of the gas at this temperature is 936 mmHg. If the amount ofthe gas is increased to 2.1g and its temperature is decreased to 17°C, then what will be the pressure of the gas? Assuming gas behaves ideally.
Answer:

Suppose, the molar mass of the gas =M g- mol^-1

So, 0.56g of the gas \(=\frac{0.56}{M}\) mol of the gas

At the initial state

⇒  \(P=\frac{936}{760}=1.23 \mathrm{~atm}, n=\frac{0.56}{M} \mathrm{~mol} \text {, }\)

V=0.41

And T = (273 + 27)K = 300K

Substituting the values of P, n, V and T in the Ideal gas equation, PV= nRT, we have

⇒ \(1.23 \times 0.4=\frac{0.56}{M} \times 0.0821 \times 300\)

∴ molar mass of the gas = 28g. mol^-1

Question 46. A cylinder capable of holding 3L water contains H₂ gas at 27°C and a pressure of atm. At STP, it is possible to fill up 10 balloons, each of which has a radius of 10cm, with the gas present in the cylinder. Find the value of P.
Answer:

The volume of each balloon

⇒ \(\frac{4}{3} \pi \mathrm{r}^3=\frac{4}{3} \pi(10 \mathrm{~cm})^3=4.19 \mathrm{~L} .\)

As the cylinder can hold 31. of water, the US volume Is 31. The volume of H0 gas required to 1111 up 10 balloons 10 × 4.19 = 41.9L.

At STP, If the volume of H₂ gas present in the cylinder is

⇒  \(V ., \text { then } \frac{1 \times V}{273}=\frac{P \times 3}{300} \text { or, } V=\frac{273 \times 3}{300} P=2.73 P\)

Even after the balloons have been filled up with 11, gas, the cylinder, still contains H gas of its volume. So, the volume of H2 gas = (2.73P- 3)L

∴ 2.73p- 3 = 41.9 or, P = 16.44

Question 47. At room temperature, 2NO + O₂→2NO₂ → N₂O₄ reaction proceeds near completion. The dimer, N₂O₄, solidifies at 262K. A 250 mL flask and a 100 mL flask are separated by a stop-cock. At 300K, nitric oxide in the longer flask exerts a pressure of 1.053 atm and the smaller one contains oxygen at 0.789 atm.

The gases are mixed by opening the stopcock and after the end of the reaction, the flasks are cooled to 220K. Neglecting the vapour pressure of the dimer, find out the pressure and composition ofthe gas remaining at 220K (assume that the gases behave ideally).
Answer:

Number of moles of NO₂ gas lit 250ml, flask

⇒ \(\frac{P V}{R T}=\frac{1.053 \times 0.25}{0.0821 \times 300}=0.01 \mathrm{~mol}\)

And that of O., in 100ml. flask, \(=\frac{P V}{R T}=\frac{0.789 \times 0.1}{0.0821 \times 300}=3.2 \times 10^{-3} \mathrm{~mol} .\)

Reaction: 2NO + O₂→2NO₂

Thus 1 mol of O₂ gns completely reacts with 2 mol of NO gns.

Therefore, 3.2 × 10^-3 mol 0f O₂ guns will react with

2 × 3.2 × 10^-3 = 6 4 ×10^-3mol if NO₂

After the completion of the reaction number of moles of NO left the reaction system = (0.01 – 6.4 × 10^-3 )

3.6 × 10^-3mol

The total volume of the reaction system = (0.25 + 0.25)L = 0.351.

If the pressure of NO gas left in the reaction system is then P × 0.35 m 3.6 × 10^-3× 0.0821 × 220 P= 0.185 atm.

Question 48. An LPG cylinder weighs 18.4kg when empty when full, it weighs 29.0 Kg and shows a pressure of 2.5 atm. In the course of 27°C, the mass of the full cylinder is reduced to 23.2 Kg. Find out the volume of the gas in cubic meters used up at the normal usage conditions, and the final pressure inside the cylinder. Assume LPG to be n-butane with a normal boiling point of 0°C.
Answer:

Mass of the gas in full cylinder=(29.0 – 18.4) kg – 10,6 kg Mass of the gas after some of is used up =- (23.2 – 18.4) 4.8kg

Mass ofthe gas used up = (10.6 – 4,8) = 5,8 kg. So, 5.8kg of gas = 5.8 kg of n-butane

⇒ \(\frac{5.8 \times 10^3}{58}=100\)

mol of H-butane [molar mass of-butane 58 g- mol^-1]

⇒ \(V=\frac{n R T}{P}=\frac{100 \times 0.0821 \times 300}{1}=24631 .\)

[at normal usage condition, P 1 atm)

Therefore, the volume of used gas at normal usage conditions = 24631. = 2.463m³ since =10-nm³]

In the cylinder, LPG exists In a liquid state which remains in equilibrium with its vapour.

So long as LPG exists in a liquid state in the cylinder, the pressure in the cylinder remains fixed. So, the pressure of the remaining gas in the cylinder will be 2.5 atm.

Question 49. An evacuated vessel weighs 50.0g when empty, 148 when filled with a liquid (d = 0.98 g-mL^-1) & 50g when filled with an ideal gas at 760 mmHg at 300K. Determine the molar mass of the gas.
Answer:

Mass of the evacuated vessel = 50.0g.

Mass of the vessel when filled with a liquid of density O.98gml^-1= 148g

∴ Volume of 98g of liquid \(=\frac{98}{0.98}=100 \mathrm{~mL}=0.1 \mathrm{~L}\)

Question 50. A gas mixture composed of N₂ and O₂ gases has a density of 1.17 g-L^-1. At 27°C and 1 atm pressure. Calculate the mass percents of N₂ and O₂ in the mixture. Assume that the gas mixture behaves like an ideal gas.
Answer: Given:

P = 1 atm and T = (273 + 27)K = 300K

∴ \(M=\frac{d R T}{P}=\frac{1.17 \times 0.0821 \times 300}{1}=28.8 \mathrm{~g} \cdot \mathrm{mol}^{-1}\)

The average molar mass of the gas mixture = 28.8 g.mol-1.

In the mixture, if the mole-fraction of N₂ is x, then the mole-fraction of O₂ is (1-x).

∴ M = 28.8g-mol^-1.

= [28 × x+32(1 -x)] g-mol^-1

Or, 4x = 32 – 28.8;

Hence, x = 0.8

Mole-fraction of N₂ = 0.8

And that of O₂ = 1- 0.8

= 0.2.

Mass per cent of

⇒ \(\mathrm{N}_2=\frac{0.8 \times 28}{0.8 \times 28+0.2 \times 32} \times 100=77.77 \%\)

And mass present 6 Of O₂ = (100-77.77)%

= 22.23%

Question 51. One mole of nitrogen gas at 0.8 atm takes 38s to diffuse through a pin-hole, whereas one mole of an unknown compound of xenon with fluorine at 1.6 atm takes 57s to diffuse through the same hole. Determine the molecular formula ofthe compound.
Answer:

At a given temperature and a pressure of P, the rate of diffusion of a gas \(r \propto \frac{P}{\sqrt{M}}\)

M= molar mass of the gas] If the rates of diffusion of N₂ and the unknown gas are r and r.) respectively, then

⇒ \(r_2 \propto \frac{P_2}{\sqrt{M_{\text {compound }}}} \text { and } r_1 \propto \frac{P_1}{\sqrt{M_{N_2}}}\)

∴ \(\frac{r_1}{r_2}=\frac{p_1}{p_2} \times \sqrt{\frac{M_{\text {compound }}}{M_{N_2}}}\)

⇒ \(\text { Given that } r_1=\frac{1}{38} \mathrm{~mol} \cdot \mathrm{s}^{-1}, r_2=\frac{1}{57} \mathrm{~mol} \cdot \mathrm{s}^{-1} \text {, }\)

p₁ = 0.8 atm and p₂ = 1.6 atm

∴ \(\frac{\frac{1}{38}}{\frac{1}{57}}=\frac{0.8}{1.6} \sqrt{\frac{M_{\text {compound }}}{28}} \text { or, } \sqrt{\frac{M_{\text {compound }}}{28}}=3\)

∴ M compound = 3 ×  28 = 252g. mol^-1

Let the molecular formula of the compound = XeFx

∴ 131 + x × 19 = 252 or, x = 6.368 ≈ 6

∴ Molecular formula ofthe compound = XeF₆

Question 52. A gas bulb of capacity contains 2.0 x 1021 molecules of nitrogen exerting a pressure of 7.57 x 103 N.m-2. Calculate the rms velocity and temperature of the gas. If the ratio of the most probable speed to the root mean square speed is 0.82, calculate the most probable speed of the molecules at this temperature.
Answer:

2.0 ×10²¹molecules of nitrogen are contained in

⇒ \(\frac{2 \times 10^{21}}{6.023 \times 10^{23}}=3.32 \times 10^{-3} \mathrm{~mol} \text { of } \mathrm{N}_2 \text { gas. }\)

Given that P = 7.57 × 10³ N.m^-2and V = 1

∴ P = 7.57× 10³N.m^-2= 7.57 × 10³Pa

⇒ \(\frac{7.57 \times 10^3}{1.013 \times 10^5} \mathrm{~atm}=0.0747 \mathrm{~atm}\)

[since 1N.m^-2 = IPa and latm = 1.013 × 10⁵ Pa]

∴ \(T=\frac{P V}{n R}=\frac{0.0747 \times 1}{3.32 \times 10^{-3} \times 0.0821}=274.05 \mathrm{~K}\)

∴ Temperature of the gas = 274.05K

we know \(c_{r m s}=\sqrt{\frac{3 R T}{M}}\)

∴ Root mean square velocity of N₂ molecules

⇒ \(=\sqrt{\frac{3 \times 8.314 \times 10^7 \times 274.05}{28}} \mathrm{~cm} \cdot \mathrm{s}^{-1}\)

= 4.94 × 10⁴cm.s^-1

⇒ \(\text { Given that } \frac{c_m}{c_{r m s}}=0.82\left[c_m=\text { most probable speed }\right]\)

∴ \(c_m=0.82 \times c_{r m s}\)

=\(0.82 \times 4.94 \times 10^4\)

= \(4.05 \times 10^4 \mathrm{~cm} \cdot \mathrm{s}^{-1}\)

∴ The most probable velocity of the molecules = 4.05×10⁴ cm.s^-1

Question 53. The composition of the equilibrium mixture (Cl₂ ⇌ 2Cl), which is attained at 1200°C, is determined by measuring the rate of effusion through a pin-hole. It is observed that at 1.80 mm Hg pressure, the mixture effuses 1.16 times as fast as Krypton effuses under the same conditions. Calculate the fraction of chlorine molecules dissociated into atoms. (Relative atomic mass of Kr = 84)
Answer:

If the rates of effusion of the equilibrium mixture and Kr gas are r₁ and r₂ then

⇒ \(\frac{r_1}{r_2}=\sqrt{\frac{M_{\mathrm{Kr}}}{M}} ;\) where M= average molar mass of the equilibrium mixture.

Given that r₁ = r₂ ×1.16

∴ \(1.16=\sqrt{\frac{84}{M}}\)

∴ M = 62.42 g.mol^-1

Let the initial amount of Cl₂ gas be 1 mol and its degree of dissociation = x. Therefore, the number of moles of Cl₂ and Cl at equilibrium will be as follows:

⇒ \(\mathrm{Cl}_2 \rightleftharpoons 2 \mathrm{Cl}\)

Initial number of moles:

Number of moles at equilibrium

∴ Total number of moles of Cl₂ and Cl in the equilibrium mixture = 1 – x + 2x = 1 + x

Average molar mass of the equilibrium mixture

⇒  \(\frac{(1-x) M_{\mathrm{Cl}_2}+2 x \times M_{\mathrm{Cl}}}{1+x}=\frac{71}{1+x} \mathrm{~g} \cdot \mathrm{mol}^{-1}\)

Now, \(\frac{71}{1+x}=62.42\) or, 62.42 + x × 62.42 = 71

∴ x= 0.1374

Fraction of Cl₂ molecules dissociated into atoms = 13.74%

Question 54. The density of the vapour of a substance at 1 atm and 500K is 0.36 Kg-m-3. The vapour effuses through a hole at a rate of 1.13 times faster than O₂ under the same condition. Determine, the molar mass, molar volume, and Compression factor of the vapour and which forces among the gas molecules are dominating attractive or repulsive. If vapour behaves ideally at 1000K, find the average translational kinetic energy of a molecule.
Answer:

If the rates of effusion ofthe vapour and O₂ gas are r1 and r2 respectively then

⇒ \(\frac{r_1}{r_2}=\sqrt{\frac{M_{\mathrm{O}_2}}{M_{\text {vapour }}}}\)

∴ \(1.33=\sqrt{\frac{32}{M_{\text {vapour }}}}\)

The molar mass of the vapour = 18.09g-mol^-1

The molar volume of the vapour

⇒\(\frac{\text { Molar mass of the vapour }}{\text { density of the vapour }}\)

= \(\frac{18.09 \mathrm{~g} \cdot \mathrm{mol}^{-1}}{0.36 \times 1000 \times 10^{-3} \mathrm{~g} \cdot \mathrm{L}^{-1}}=50.25 \mathrm{~L} \cdot \mathrm{mol}^{-1}\)

⇒ \(Z=\frac{P V_m}{R T}=\frac{1 \times 50.25}{0.0821 \times 500}=1.224\)

[Vm = molar volume] Hence, Z >1

Z> 1 indicates that the vapour shows a positive deviation from ideal behaviour. This kind of deviation occurs in gas when the effect of intermolecular repulsive forces dominates over the effect of intermolecular attractive forces.

Average translational kinetic energy of a molecule \(=\frac{3}{2} k T\)

⇒ \(\frac{3}{2} \times 1.32 \times 10^{-23} \mathrm{~J} \cdot \mathrm{K}^{-1} \times 1000 \mathrm{~K}=1.98 \times 10^{-20} \mathrm{~J}\)

Question 55. The compressibility factor for 1 mole of a van der Waals gas at 0°C and 100 atm pressure is 0.5. Assuming that the volume of a gas molecule is negligible, calculate the van der Waals constant, a.
Answer:

Compressibility factor \(Z=\frac{P V}{n R T}\)

Given that Z = 0.5, n = 1 mol, T – 273K and = 100 atm

∴ \(V=\frac{Z \times n R T}{P}=\frac{0.5 \times 1 \times 0.0821 \times 273}{100} \mathrm{~L}=0.112 \mathrm{~L}\)

For 1 mol of a real gas, the van der Waals equation is—

⇒ \(\left(P+\frac{a}{V_m^2}\right)\left(V_m-b\right)=R T\left[V_m=\text { molar volume }\right]\)

As the volume of a gas molecule is assumed to be negligible, but, and hence Vm-b~ Vm

∴ \(\text { or, } \frac{P V_m}{R T}=1-\frac{a}{\mathrm{RT} V_m} \quad \text { or, } Z=1-\frac{a}{R T V_m}\)

⇒ \(\text { or, } \frac{P V_m}{R T}=1-\frac{a}{\mathrm{RT} V_m} \quad \text { or, } Z=1-\frac{a}{R T V_m}\)

⇒ \(\text { or, } 0.5=1-\frac{a}{0.0821 \times 273 \times 0.112} ; \quad \text { hence, } a=1.255\)

Question 56. The pressure in a bulb dropped from 2000 to 1500 mm of Hgin 47 min when the contained oxygen leaked through a small hole. The bulb was then evacuated. A mixture of oxygen and another gas of molar mass 79 in the molar ratio of 1: 1 at a total pressure of 4000 mm of Hg was introduced. Find the molar ratio of two gases remaining in the bulb after 75 min.
Answer:

Decrease in pressure of O₂ in 47 min=2000- 1500=500mmHg

Decrease in pressure of O₂ in 74 min = \(=\frac{500}{47} \times 74=787.23\) mm kg

In the mixture, the mole ratio of O₂ and the other gas =1: 1

So, mole-fraction of each of O₂ and other gas in the mixture \(=\frac{1}{2}\)

In the mixture, the partial pressure of \(\mathrm{O}_2=\frac{1}{2} \times 4000=\) 2000 mmHg and that of the other gas

⇒ \(=\frac{1}{2} \times 4000 \mathrm{mmHg}=\) = 2000 mm kg If the rates of effusion of 02 gas and the other gas are r1 and respectively, then

⇒ \(\frac{r_1}{r_2}=\sqrt{\frac{M}{M_{\mathrm{O}_2}}}\) [M= molar mass of other gas]

Now,\(r_1=\frac{787.23}{74} \mathrm{mmHg} \cdot \mathrm{min}^{-1}\)

= 10.63 mm hg. min^-1

∴ \(r_2=r_1 \times \sqrt{\frac{M_{\mathrm{O}_2}}{M}}=10.63 \sqrt{\frac{32}{79}}=6.76 \mathrm{mmHg} \cdot \mathrm{min}^{-1}\)

Now, \(r_2=\frac{\begin{array}{l}
\text { the decrease in pressure of the other gas } \\\end{array}}{74}\)

∴ The decrease In pressure of the other gas = r₂ × 74 = 6.76 × 74 = 500.24 mmHg

Therefore, In the mixture, partial pressure of O₂ gas

= (2000- 787.23) 1212.77mmHg and that of the other gas =(2000- 500.24)=

1499.70 mm g Hence, the ratio of mole-fraction of the other gas to O2 gas

=1499.70: 1212.77 = 1.236: 1 In the mixture, the molar ratio of the two gases = 1.230: 1.

NCERT Class 11 Chemistry Chapter 6 Chemical Thermodynamics Very Short Question Answers

Question 1. Which type of system does not interact with its surroundings? Classify the following systems into open, closed, and isolated systems: a plant certain amount of a liquid enclosed in a container with rigid, impermeable, and adiabatic wall
Answer:

1. Isolated System
2. Open
3. Isolated

Question 2. If the volume and density of 5g of pure iron sample are ‘ V’ and ‘ d.’ respectively then what will be the volume and density of 10 g of the same sample?
Answer: Volume = 2 V; density = d

Question 3. The specific heat capacity of 10g of a sample of aluminum is x cal. g^-1 K^-1 . Is the value of the specific heat capacity of 5g of that sample\(\frac{x}{2}\) cal .g^-1 K^-1?
Answer:  No, because it is a state property of the system.

Chemical Thermodynamics VSAQs Class 11 Chemistry Chapter 6

Read and Learn More NCERT Class 11 Chemistry Very Short Answer Questions

Question 4. On which factors does the change in a state function depend?
Answer: Upon initial and final states of the system.

Question 5. The initial state of a system is ‘This system participates in the following process: A→B→C→A. What will be the change in the internal energy of the system in this process?
Answer: Zero

Question 6. At T K, what will be the value of (H- U) for 1 mol of ideal gas?
Answer: RT

Question 7. In an isothermal expansion of an ideal gas, both ΔH and ΔU are zero. What will be the values of ΔU and ΔH in the isothermal compression of an ideal gas?
Answer: ΔH = 0; ΔU = 0

Question 8. What will be the value of the change in internal energy of a process occurring in an isolated system?
Answer: Zero

Question 9. In a process, q cal heat is absorbed by a closed system. If work done by the system is w cal, then what will be the value of the change in internal energy (ΔU) in this process?
Answer: ΔU = q-w,

Question 10. For a process occurring in a closed system, ΔU = q. If only pressure-volume work is performed by the system then which type of process is this?
Answer: Isochoric

Question 11. The amount of heat released by a system at constant pressure is 20 kj. What will be the value of ΔH in this process?
Answer: ΔH = -20 kj

Question 34. For an ideal gas C V,m = J mol^-1 K^-1. What will be the value of Cp m?
Answer: 20.784 J.mol^-1-K^-1?

Question 12. A liquid in a closed adiabatic container is stirred. Among ΔU, w, and q, which one will be zero?
Answer: q = 0

Question 13. If the temperature of I mol of an ideal gas is doubled then what will be the change in value of internal energy? Will it increase, decrease, or remain the same?
Answer: Will increase.

Class 11 Chemistry Chapter 6 Chemical Thermodynamics Very Short Questions & Answers

Question 14. 2H₂ + O₂-2H₂O , AH = -571.6 kj. Does this equation express the thermochemical equation for the formation of H₂O?
Answer: No, because the physical states of the reactants and products are not mentioned in the reaction.

Question 15. What temperature and pressure are usually considered as the standard state of a substance?
Answer: Pressure = 1 atm, any temperature may be considered.

Question 16. Which allotropic form of carbon is considered a source of carbon in the formation reactions of carbon compounds at 25°C and 1 atm?
Answer: C(graphite,s).

Question 17. Which of the following two reactions indicates the formation reaction of HI(g) at 25°C and 1 atm?

⇒ \(\frac{1}{2} \mathrm{H}_2(g)+\frac{1}{2} \mathrm{I}_2(g) \rightarrow \mathrm{HI}(g)\)

⇒ \(\frac{1}{2} \mathrm{H}_2(g)+\frac{1}{2} \mathrm{I}_2(s) \rightarrow \mathrm{HI}(g)\)

Answer: Reaction because the standard state of means than iodine is I2(s).

Question 18. Between O₂(g) and O₃(g), whose standard enthalpy of formation (ΔH0f) is taken as zero at 1 atm and 25°C?
Answer: O₂ (g) because at 25°C the standard state of oxygen is O₂(g)

Question 19. In which of the following reactions the standard heat of reaction is equal to the standard heat of formation of CaBr₂(s) at 25°C?

• Ca(s) + Br₂(l)-CaBr₂(s)
• Ca(s) + Br₂(g)-CaBr₂(s)

Answer: Reaction (1), because at 25X the standard state of bromine is Br2(l).

Question 20. Heat is required to vaporize 1 g of water at 100°C and 1 atm is 2.26kj. What is the enthalpy of vaporization of water at this temperature and pressure?
Answer: 40.68 kj

Question 21. 1 mol of H₂O(Z) is formed when 1 mol of H+ ions and 1 mol of OH- ions react together in aqueous solution. Does this reaction represent the formation reaction of water?
Answer: No, because H₂O(f) is not formed from its constituent elements.

Question 22. Consider the reactions

• A₂(s) + B₂(g)-+A₂(g) + B₂(g); AH = -x kj
• A₂(g) + B₂(g)-+2AB(g) ; AH = -y kj .

What is the value of the change in enthalpy for the following reaction A₂(s) + B₂(g)-+2AB(g)?
Answer: — (X + y) kJ ;

Question 23. S(monoclinic, s)-S(rhombic, s). What is the enthalpy change of this process called?
Answer: Heat of transformation

NCERT Solutions Class 11 Chemistry Chapter 6 Thermodynamics VSAQs

Question 24. \(\mathrm{H}_2(g)+\frac{1}{2} \mathrm{O}_2(g) \rightarrow \mathrm{H}^{+}(a q)+\mathrm{OH}^{-}(a q) ;\) \(\Delta H^0=-228.5 \mathrm{~kJ} \cdot \mathrm{mol}^{-1} \text { if } \Delta H_f^0\left[\mathrm{H}^{+}\right]=0\) then what will be the value of AH0Of[OH-] ?
Answer: -228.5 kj mol^-1

Question 25. The bond dissociation energies of three A-B bonds in ΔB3(g) molecule are x,y, and zkj-mol^-1 respectively. What is the bond energy of the A- B bond?
Answer: l/3(x + y + z)kJ-mol^-1

Question 26. Why is the heat of reaction of a reaction occurring in a bomb calorimeter equal to the change in internal energy of the reaction system?
Answer: The volume of the reaction system remains the same.

Question 27. In the case of diatomic gaseous I molecule 33. -7.43kJ -mol^-1 ;
Answer: In the case of diatomic gaseous molecules.

Question 28. What will be the difference between ΔH and ΔU in the combustion reaction of C₁₀H₈(g) at 25°C?
Answer: -7.43kJ -mol^-1

Question 29. Write down the relation between ΔH and ΔU for the following reaction: CH₃COOH(aq) + NaOH(a<y)-CH₃COONa(ag) + H2O(l)
Answer: zero

Question 30. If the bond energy of the C- H bond is +416.18 kj .mol^-1, then what will be the enthalpy of the formation of the C-H bond?
Answer: 416.18kJ. mol^-1

Question 31. What is the most important feature of Hess’s law?
Answer: It is used to determine the heat of the reaction;

Question 32. The standard bond dissociation energy of A2(g), B2(g) and AB(g) molecules are x,y, and zkj-mol-1 respectively. What will be the standard enthalpy of the formation of AB(g)?
Answer: [z- 1 /2(x + y)]kj . mol^-1

Question 33. At temperature T K the difference between ΔH and ΔU for the following reaction is \(+\frac{1}{2} R T: \mathrm{A}+\frac{1}{2} \mathrm{~B}_2(\mathrm{~g}) \rightarrow \mathrm{AB}(\mathrm{g}).\) What is the physical state of (solid or gas)?
Answer: Soild [A(s)]

Question 34. Give an example of a spontaneous process in which the change in enthalpy of the system is positive.
Answer: Melting of ice above 0°C,

Chemical Thermodynamics Very Short Questions and Answers Class 11

Question 35. What will be the signs of enthalpy change and entropy change for a process to be spontaneous at all temperatures?
Answer: ΔH < 0 , ΔS > 0

Question 36. What will be the signs of AG for melting ice at 267K and 276K temperature and atm pressure?
Answer: ΔG> 0 ΔG < 0

Question 37. Water and ice remain in equilibrium at 0°C and 1 atm pressure. What will be the value of AG and the sign of the S system at this equilibrium?
Answer: ΔG = 0 , ΔS_sys>0,

Question 38. Which one of the following relation or expression is true for a spontaneous process of ΔG = 0, ΔH=TΔS, ΔG > 0, ΔG < 0?
Answer: AG<0

Question 39. What will be the sign of entropy change for the process I2(g)-+I2(s)?
Answer: ΔS = -ve

Question 40. What will be the change in entropy of the surroundings in a spontaneous process occurring in an isolated system?
Answer: Zero

Question 41. Is the entropy of the universe constant?
Answer: No, increases continuously

Question 42. Give an example of a process in which the change in enthalpy of the system is negative.
Answer: Solidification of liquid

Question 43. what sign (or-) of entropy change in an endothermic relation makes the reaction Non-spontaneous at any temperature?
Answer: ΔS < 0,

Question 44. In which case the Δ_sys will lie maximum between die following two processes ice – water I₂(s) – l₂(g)
Answer: I₂(s) – l₂(g)

Question 45. Predict the sign of AS0 for the given reaction. \(2 \mathrm{H}_2 \mathrm{~S}(g)+3 \mathrm{O}_2(g) \rightarrow 2 \mathrm{H}_2 \mathrm{O}(g)+2 \mathrm{SO}_2(g)\)
Answer: – ve

Question 46. Does die Gibbs free energy of a substance decrease or increase if the amount of the substance is increased?
Answer: Will increase

Class 11 Chemistry Chemical Thermodynamics VSAQs

Question 7. In a process, the value of the change in entropy of the die system and its surroundings are x and -yj. IC^-1 . If x > y, then will the process be spontaneous?
Answer: No

Question 48. The change in entropy of the system in a process A -4 B -4 C is 25 J K^-1. If the change in entropy of the system in step B → C is 15 J K^-1, then what will be the change in entropy of the system in step B→ A?
Answer: -10J.K^-1

Question 49. Which is not a state function: (q+w), w, H, G?
Answer: ‘ w’ is not a state function it is not a property of the system.

Question 50. In a process, a system absorbs 500J of heat and performs 800J of work. In the process, q =__________ w =__________
Answer: As the system absorbs heat. and performs work, q is + ve and w is -ve. Hence, q = +500 J and w – -800 J.

Question 51. In a process, a system releases 500J of heat and work done on the system is 300 J. In the process, q = w =
Answer: The system releases heat and work is done on the system i.e., q is -ve and w is +ve so, q = -500J, w = +300J.

Question 52. Is rusting of iron a spontaneous process? What is the entropy of a system? Give its mathematical definition. What is its unit?
Answer: Rusting of irony is a spontaneous process.

Question 53. For a reversible process A = -20 J. K-1. What will be the value of ASsun in this process?
Answer: In a reversible process, ΔS_sys = (-) ΔS_surr As, Δ = -20 J⋅K-1.So, ΔS_surr = +20 J.K-1

Question 54. Write the SI unit of energy.
Answer: The SI unit of entropy is I K-

Question 55. A occurring in an isolated system does not have any effect on its surroundings and the process is ft influenced by its surroundings. Why?
Answer: An isolated system does not interact with its surroundings

Question 56. In a process, if the heat released by the system and 80 work done on the system are 90 ) and 120), respectively, then what will he of q and w?
Answer: q=-90J ad w=+120J.

Question 57. If the specific heat capacity and molecular mass of a gas are cp and M respectively then what will be the molar heat capacity of the gas?
Answer: Molar heat capacity of tyre gas, C_p,m = c_p x M.

Question 58. Give examples of two processes where AS is zero
Answer: Adiabatic reversible process Cyclic process

Question 59. What will be the change in entropy in an irreversible cyclic process?
Answer: As entropy is a state function, the change in entropy in either a reversible or an irreversible cyclic process is zero.

Question 60. Are the given statements correct? If bent Is absorbed In a chemical reaction, the reaction cannot be spontaneous. The entropy of the system may decrease In a reaction, but the reaction can occur spontaneously
Answer: The statement is incorrect is correct

Question 61. Which of the following conditions favours the spontaneity of a reaction at a constant temperature and pressure? ΔH > 0 , ΔH < 0 , ΔS > 0 , ΔS < 0
Answer: The conditions of ΔH < 0 and ΔS > 0 favour a reaction to be spontaneous at a constant temperature and pressure.

Question 62. For 311 isolated systems, ΔU = 0, what will be AS?
Answer: For a spontaneous process occurring in an isolated system AS is positive (i.e., ΔS > 0 ).

Question 63. Write the SI unit of entropy
Answer: SI unit of entropy: J. K-1. mol-1

Question 164. State the condition of spontaneity and equilibrium in terms of Gibbs free energy change of a system.
Answer: The condition of spontaneity regarding Gibbs free energy is AG < 0. The condition of equilibrium in terms of Gibbs free energy is AG = 0.

Question 165. Which variable is kept constant in an isochoric process?
Answer: Volume is kept constant in an isochoric process.

Question 166. In a process, 600J of heat is absorbed by a system, and 300J of work is done by the system. Calculate the change in internal energy of the system
Answer: Given: q = +600J, w = -300J. So, change in internal energy, ΔH = q + w = (600- 300)J = 300J

NCERT Class 11 Chemistry Chapter 6 Thermodynamics Short Answer Questions & Answers

NCERT Solutions For Class 11 Chemistry Chapter 6 Chemical Thermodynamics Fill In The Blanks

Question 1. The sign of A U in the adiabatic expansion of a gas is ____________.
Answer: -ve

Question 2. In a process q > 0, but w = 0, So, the internal energy of the system will (Increase/decrease) ____________
Answer: Increase

Question 3. According to first Jaw, for a cyclic process q+w =____________
Answer: 0

Question 4. The volume of a substance is a property while the molar volume of a substance is an____________property.
Answer: Extensive, intensive

Chapter 6 Chemical Thermodynamics VSAQs NCERT Solutions

Question 5. The specific heat capacity of a substance is a; cal. g-1.°C^-1. The specific heat capacity of 100 g of that substance will be____________
Answer: x cal. g-1 °C^–1

Question 6. The molar heat capacity of a substance at constant pressure is ____________than that at constant volume.
Answer: Greater;

Question 7. In the vaporization of water, the signs of q and w are ____________and respectively.
Answer: q = + ve , w = -ve;

Question 8. For a process occurring at constant volume, U= + 10 kj. In this process, q = ____________
Answer: q = +10 kJ;

Question 9. In isothermal expansion of 1 mol of an ideal gas, q = + 12 kJ. The value of w = and A U =____________
Answer: w = -12 kJ , AU = 0

Question 10. In an alchemical reaction, if the total enthalpies of reactants and products are HR and Hp respectively then Hp > HR for____________ reaction and HR > Hp for ____________reaction.
Answer: Endothermic, exothermic

NCERT Class 11 Chemistry Thermodynamics VSAQs

Question 11. At 25°C, the standard state of liquid ethanol means ____________ethanol at 25 °C and____________ pressure.
Answer: Pure liquid, 1 atm

Question 12. Given: C₃H₈(g) + 5O₂(g)→3CO₂(g) + 4H₂O(l) and C₃H₂(g) + 5O₂(S)→3CO₂(g) + 4H₂O(g). At a fixed temperature and pressure between these two reactions the heat evolved in the second reaction is more than that in the first one.
Answer: Less

Question 13. At 25°C and 1 atm, the standard reaction enthalpy for the reaction C(graphite, s) + O₂(g)→CO₂(g) is the ____________ of CO₂(g).
Answer: Standard enthalpy of formation;

Question 14. At 25°C and 1 atm, standard reaction enthalpy for the reaction, CH4(g) + 2O₂(g)→ CO₂(g) + 2H₂O(Z) is ____________of CH₄(g).
Answer: Standard enthalpy of combustion

Question 15. The change in enthalpy for die reaction HCN(aq) + NaOH(aq)—>NaCN(aq) + H₂O(Z) is ____________than the change ih! ^enthalpy for the reacdon HCI {aq) + NaOH(aq)→NaCl(aq) + H₂O(/).
Answer: Less

Question 16. The change in enthalpy for the process KCl(s) + 100H₂0(l)-KCl(100H₂O) is called____________.
Answer: Integral heat of solution

Question 17. At 25°C and 1 atm if the bond energy of Cl₂(g) is 242 kj.mol^-1, then the standard enthalpy of atomization of chlorine at the same temperature = ____________.
Answer: 121KJ.mol^-1

Question 18. In a reaction Δ_sys= xJ.K^-1 and ΔS_surr = -yJ.K^-1. The reaction will be spontaneous if ____________
Answer: x>y

Question 19. In the cyclic process ΔB Δ the changes in entropy of the system are ΔS₁, ΔS_2, and ΔS₃. ΔS₁ + ΔS₂ + ΔS₃ =____________.
Answer: Zero

Question 20. NH₄Cl(s) + H₂O(l) → NH₄⁺(aq) + Cl^–(aq). It is an endothermic process. In this process the signs (+ or -) of____________ ΔS_sys and ΔS_surr  are and respectively.
Answer: Δ_sys > 0 and ASsun < 0

Very Short Question and Answer Chemical Thermodynamics Class 11

Question 21. A reaction is non-spontaneous at all temperatures but the____________
reverse reaction is spontaneous at all temperatures. The signs (+ or – ) of ΔH and ΔS for the reverse reaction are____________and respectively.
Answer:  ΔH < 0 and Δ_sys

Question 22. In an exothermic process Δ_sys< 0. In this reaction the sys sign (+ or – ) of ASsurr is____________. This reaction will be spontaneous if the numerical value of Ssys is higher than that of ASsurr.
Answer: +ve, less

Question 23. In a spontaneous process occurring at constant pressure and at temperature T K, ΔH > 0, ΔS > 0. In this process, the numerical value of ΔH is ____________ than that of____________.
Answer: Less, TΔS

Question 24. A process is always spontaneous at all temperatures if the enthalpy change is and entropy changes is _______
Answer: —ve and +ve.

NCERT Solutions For Class 11 Chemistry Chapter 8 Redox Reactions Very Short Questions And Answers

Question 1. In which of the following two reactions does HNPO₃ not act as an oxidizing agent? Explain 
Answer: 2

Question 2. Which one of the following two reactions is a redox reaction?
Answer: 2

Question 3. Arrange the following compounds in increasing order of the oxidation number of S. Na₂S₄O₆, H₂S₂O₇, H₂SO₃, Na₂S₂O₃
Answer: Na₂S₂O₃ < Na₂S₄Og < H₂SO₃ < H₂S₂O₇

Read and Learn More NCERT Class 11 Chemistry Very Short Answer Questions

Question 4. Give an example of a compound In which The mime element exists In two different oxidation slates.
Answer: NH₄NO₃

Question 5. Given an example of a compound In which the oxidation number of N=+1.
Answer: N₂O

Redox Reactions VSAQs Class 11 Chemistry Chapter 8

Question 6. Give an example of a compound In which the oxidation number of O r₂.
Answer: OF₂

Question 7. What Is the oxidation number of Fe In Po(CO)s?
Answer: Zero(0)

Question 8. What is the oxidation number of sodium In sodium amalgam?
Answer: Zero(0)

Question 9. Give an example of a compound In which the oxidation number and valency of an element In the compound are the same.
Answer: CCl₄

Question 10. What are the oxidation numbers of three C -atoms In C₃O₂?
Answer:

⇒ \(\mathrm{O}=\stackrel{+2}{\mathrm{C}}=\stackrel{0}{\mathrm{C}}=\stackrel{+2}{\mathrm{C}}=\mathrm{O},\)

Question 11. What Is the oxidation number of carbon In CCOCH₃?
Answer: -4/3

Question 12. What type of redox reaction does the given reaction belong to? \(2 \mathrm{H}_2 \mathrm{~S}+\mathrm{SO}_2 \rightarrow 2 \mathrm{H}_2 \mathrm{O}+3 \mathrm{~S}\)
Answer: Comproportlonation

Class 11 Chemistry Chapter 8 Redox Reactions Very Short Answer Questions & Answers

Question 13. Which of the following Is unable to participate in disproportionation reaction? CIO-, ClO₂, ClO₃, ClO₄
Answer: CIO¯₄

Question 14. In which of the following ions does Fe exist in the same oxidation state? \(\left[\mathrm{Fe}(\mathrm{CN})_6\right]^{4-},\left[\mathrm{Fe}(\mathrm{CN})_6\right]^{3-},\left[\mathrm{Fe}(\mathrm{CN})_5 \mathrm{NO}^{2-}\right.\)
Answer: [Fe(CN₆)]_4‾ and [Fc(CN)gNO]^2-

Question 15. What is the equivalent mass of CuSO₄ in the given reaction? 2CuSO₄ + \(2 \mathrm{CuSO}_4+4 \mathrm{KI} \rightarrow \mathrm{Cu}_2 \mathrm{I}_2+\mathrm{I}_2+\mathrm{K}_2 \mathrm{SO}_4\)
Answer: M

Chapter 8 Redox Reactions Very Short Answer Solutions Class 11

Question 16. What is the average oxidation number of Fe in \(\mathrm{Fe}_4\left[\mathrm{Fe}(\mathrm{CN})_6\right]_3\)?
Answer: \(+\frac{18}{7}\)

Question 17. Which one is the oxidizing agent in the given reaction: Which element In oxidized and which element Is reduced In the reaction, \(\mathrm{AsO}_2^{-}+\mathrm{Sn}^{2+} \rightarrow \mathrm{As}+\mathrm{Sn}^{4+}+\mathrm{H}_2 \mathrm{O}\)
Answer: AsO‾²

Question 18. Which element In oxidized and which element Is reduced In the reaction, 4KCIO₂(g) → 3KClO₄(g) + KCl(g)?
Answer: Cl is reduced and oxidized simultaneously

NCERT Solutions Class 11 Chemistry Chapter 8 Redox Reactions VSAQs

Question 19. How many moles of electrons will be required to reduce 1 mol NO₃ ion to hydrazine in the acidic medium?
Answer: 7 mol

Question 20. In an alkaline medium, ClO₂ oxidizes H₂O₂ to O₂ and itself reduces to Cl^– ion. How many moles of H₂O₂ will be oxidized by 1 mol of ClO₂?
Answer: 2.5 mol

Question 21. In the basic medium, KNO₂ is oxidized by KMnO₄, forming KNO₃. How many moles of KMnO₄ are required to oxidize 1 mol of KNO₂?
Answer: 2/3 mol

Question 22. Calculate— the number of mol of KMnO₄ required to oxidize 1 mol of ferrous oxalate in an acidic medium, The number of mol of K₂Cr₂O₇ required to oxidize 1 mol of ferrous oxalate in an acidic medium
Answer: 0.6 mol

Question 23. Calculate the equivalent mass of the underlined Compounds.
Answer: 183.75 16.5

Very Short Questions and Answers Redox Reactions Class 11

NCERT Solutions For Class 11 Chemistry Chapter 8 Redox Reactions Fill In The Blanks

Question 1. Oxidation number of N in Mg₃N₂ is_________________.
Answer: -3

Question 2. An element can exist in +1, 0, +5 oxidation states. In a compound, if the element exists in a state, then the compound can participate in a disproportionation reaction.
Answer: +1

Question 3. The oxidation number of S in (CH₃)₂SO is_________________.
Answer: +4

Question 4. The number of electron(s) involved in the reaction, IO¯₃ →I‾ in basic medium, is_________________.
Answer: 6

NCERT Class 11 Chemistry Chapter 8 VSAQs on Redox Reactions

Question 5. The equivalent mass of SO₂ in the reaction, SO₂ →\(\mathrm{SO}_4^{2-}\) in acidic medium is_________________.
Answer: 32

Question 6. \(\mathrm{CrO}_4^{2-}+x \mathrm{H}_2 \mathrm{O}+y e^{-} \rightarrow\left[\mathrm{Cr}(\mathrm{OH})_x\right]^{-}+x \mathrm{OH}^{-}\), where y =_________________.
Answer: 3

Question 7. The oxidation number of Mo in [Mo₂O₄-(C₂H₄)₂(H₂O₂)]²⁺ is_________________.
Answer: +5

NCERT Solutions For Class 11 Chemistry Chapter 8 Redox Reactions Short Question And Answers

Question 1. An oxidizing agent KH(IO₃)₂ in the presence of 4.0 (N) HCI gives KCl as a product. Determine the equivalent weight of KH(IO₃)₂. [K = 39, I = 127]
Answer:

According to the question,

In the reaction, the change in oxidation number of each I -atom = + 5- (+1) = 4 units.

So, for two -atoms present in 1 molecule of KH(IO₃)₂, the total change in oxidation number

= 2 × 4 = 8 units.

So, in acid medium, the equivalent weight of KH(IO₃)₂

⇒ \(\frac{\text { Molecular weight of } \mathrm{KH}\left(\mathrm{IO}_3\right)_2}{\text { Total change in oxidation number }}\)

= \(\frac{390}{8}=48.75\)

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Question 2. Find the oxidation number of carbon in methanal and methanoic acid.
Answer:

Methanal: The oxidation number of C in the HCHO molecule = 0.

Methanol acid: Suppose the oxidation number of C in methanoic acid.

2 × (+1)(for two H-atoms)  + x + 2 × (-2) (for two O-atoms)  = 0

2 × (+1)+ x + 2 × (-2) = 0

Hence, the oxidation number of C in the HCOOH molecule = +2.

Short Question and Answers Class 11 Chemistry Chapter 8 Redox Reactions

Question 3. What will be the change in the oxidation number of Mn when MnO₂ is melted with solid KNO₃ & NaOH?
Answer:

Potassium manganate is produced when MnO₂ is melted in the presence of solid KNO₃ and NaOH.

⇒ \(\stackrel{+4}{\mathrm{MnO}_2}+2 \mathrm{KOH}+\mathrm{KNO}_3 \longrightarrow \mathrm{K}_2 \stackrel{+6}{\mathrm{MnO}}{ }_4+\mathrm{KNO}_2+\mathrm{H}_2 \mathrm{O}\)

So in this reaction, the oxidation number of Mn increases from +4 to +6 i.e., a change in the oxidation number of

Mn = 6 – 4

= 2 unit

Question 4. The compound AgF₂ is unstable. However, if formed, the compound acts as a very strong oxidizing agent. Why?
Answer:

AgF₂ can be prepared, although it is not a stable compound. This is because the oxidation state of Ag in AgF₂ is +2, which is not the stable oxidation state of Ag.

The stable oxidation state of Ag is +1. As a result, Ag²⁺ in AgF₂ quickly reduces to Ag+ by gaining an electron (Ag²⁺+ e→Ag⁺). This brings about the instability of AgF₂ and makes it a very strong oxidizing agent.

Question 5. Write formulas for the following compounds:

1. Mercury chloride
2. Nickel sulphate
3. Tin 4
4. Oxide
5. Thallium sulphate Iron(3)
6. Sulphate Chromium(3) oxide

Answer:

1. HgCl₂
2. NiSO₄
3. SnO₂
4. TI₂SO₄
5. Fe₂(SO₄)₃
6. Cr₂O₃.

NCERT Solutions Class 11 Chemistry Chapter 8 Redox Reactions Short Questions & Answers

Question 6. A clement has three oxidation numbers, +6, +7, and +4. If it exhibits a +7 oxidation number in a compound, will the compound be able to participate In a disproportionation reaction?
Answer:

The compound cannot undergo a disproportionation reaction. This is because the element in the compound exists in its highest oxidation state. The compound would have been able to undergo a disproportionation reaction if the element existed in the +6 oxidation state in the compound, as this oxidation state lies between the oxidation states +7 and +4.

Question 7. For an element to undergo a disproportionation reaction, at least how many oxidation states should the clement exhibit?
Answer:

When an element undergoes a disproportionation reaction or oxidation state, the element changes in the following way

Intermediate- Higher oxidation + Lower oxidation

Example: The reaction of Cl₂ with cold and dilute NaOH is a disproportionation reaction.

So. an element will be able to undergo disproportionation reactionist exhibits at least three oxidation states

Question 8. An element can show 0, 1, and +5 oxidation states. The oxidation numbers of the element In two compounds are -1 and +5. Is a disproportionation reaction involving these two compounds possible?
Answer:

In a comproportionation reaction, two reactants in which a particular element exists in different oxidation states, react to form a substance in which that element exists in an intermediate oxidation state.

The given oxidation states of the element in two compounds are -1 and +5. So, if these two compounds together undergo a compo-portionation reaction, they will form a substance in which the element will exist in a zero oxidation state. This oxidation state lies between -1 and +5. Hence, the two compounds together can undergo a comproportionation reaction

Question 9. Find the oxidation state of C-l and C-2 In CH₃CH₂OH.
Answer:

The oxidation number of the three H -atoms attached to C-2 = +1. Therefore, the total oxidation number of three Hatorns = +3. For the C — C bond, the oxidation number of the C-2 atom does not change.

So, the oxidation number of the C-2 atom =-3. Now, die total oxidation number of two H -atoms attached to the C-1 atom =+2. Again, the oxidation number of the —OH group attached to the C-1 atom =-l.

Hence, the total oxidation number of two H -atoms and one linked to the C-l atom =+→2 + (-1) = +1. Thus, the oxidation number of C-1 Hence, die oxidation states of C-1 and C-2 in CH₃CH, OH are -1 and -3 respectively.

Class 11 Chemistry Redox Reactions Short Answer Questions

Question 10. 1 mol N₂H₄ loses 10 mol of electrons with, the formation of 1 mol of a new compound Y. If the new compound contains the same number of N-atoms then what will be the oxidation number of nitrogen in the new compound? (Assume that the oxidation number of the H -atom does not change.
Answer:

The oxidation number of each N -atom in N₂H₂ = -2 As given, 1 mol N₂H₄→1 mol Y + 10 moles.

Suppose, the oxidation of a million of N in its molecule of Y – x.

Total oxidation uninbor of two N -Moms In Y molecule -Oxidation number of two N atoms In N₂H₄ molecule = 2 × (-2) + I or, x = + 3

The oxidation number of each N-atom In compound Y = +3

Question 11. Fluorine reacts with ice and results in the change: H₂O(s) + F₂(g)-+HF(g) + HOF(g); Justify that this reaction is a redox reaction.
Answer:

⇒ \(\stackrel{+1}{\mathrm{H}}_2 \stackrel{-2}{\mathrm{O}}^{-2}(s)+\stackrel{0}{\mathrm{~F}}{ }_2(g) \rightarrow \stackrel{+1}{\mathrm{H}} \stackrel{-1}{\mathrm{~F}}^{}(g)+\stackrel{+1}{\mathrm{HOF}}^{0-1}(g)\)

In the reaction, H₂O undergoes oxidation because the oxidation number,0 increases (-2 to 0 and F₂ undergoes reduction as the oxidation number of F decreases (0 to -1). Hence, it is a redox reaction.

Redox Reactions Short Answer Questions Class 11 NCERT

NCERT Solutions For Class 11 Chemistry Chapter 8 Redox Reactions Warm-Up Exercise Question And Answers

Question 1. Give two examples of nitrogen-containing compounds, in one of which, the oxidation state N-atom is +1, while in the other compound, N-atoms exist in two different oxidation states.
Answer:

The Oxidation number of N in N₂O is +1. The Oxidation Numbers Of Two N-atoms in NH₄NO₃ are -3 and +5 respectively

Question 2. CO₃O₄ is an oxide of CO₃ and CO₂ If its formula is Cox(2)Co,(m)O₄, then what is the value of x and y?
Answer:

The sum of the oxidation number of the elements in a compound is equal to zero.

So, for Co₂(2)CO_y(3)O₄, 2x+3y-4 × 2 = 0

Or, 2x+ 3y = 8

The only solution for this equation is x = 1 and y = 2.

Question 3. How many electrons should A₂H₃ liberate so that In the new compound, A shows an oxidation number of \(-\frac{1}{2}\)?
Answer:

Let, A₂H₃ will liberate x electrons.

Therefore \(2 \times\left(-\frac{1}{2}\right)+3 \times(+1)=+x\)

Or, -1+3 = +x or, x = 2.

NCERT Class 11 Chemistry Redox Reactions Short Questions

Question 4. Give an example of an oxygen-containing compound for each of the following oxidation states of oxygen: \(+1,-\frac{1}{2},-1\)
Answer:

The oxidation states of O in O₂F₂, KO₂ And H₂O₂ are \(+1,-\frac{1}{2} \text { and }-1\) respectively

Question 5. Arrange the following compounds in increasing order of the oxidation number of N. Mg₃N₂, NH₂OH, (N₂H₅)₂SO₄, [CO(NH₃)₅CI]CI₂
Answer:

⇒ \(\mathrm{Mg}_3 \mathrm{~N}_2<\left(\mathrm{N}_2 \mathrm{H}_5\right)_2 \mathrm{SO}_4<\mathrm{NH}_2 \mathrm{OH}<\left[\mathrm{Co}\left(\mathrm{NH}_3\right)_5 \mathrm{Cl}\right] \mathrm{Cl}_2 ;\) 

Question 6. What are the values of a and b in the given redox reaction?

⇒ \(a \mathrm{KMnO}_4+\mathrm{NH}_3 \rightarrow b \mathrm{KNO}_3+\mathrm{MnO}_2+\mathrm{KOH}+\mathrm{H}_2 \mathrm{O}\)

Answer:

a = 8,b = 3

Chapter 8 Redox Reactions Short Question Solutions Class 11

Question 7. Write the half-reactions of the given redox reaction

⇒ \(\mathrm{UO}^{2+}+\mathrm{Cr}_2 \mathrm{O}_7^{2-}+\mathrm{H}^{+} \rightarrow \mathrm{UO}_2^{2+}+\mathrm{Cr}^{3+}+\mathrm{H}_2 \mathrm{O}\)

Answer:

⇒ \(\mathrm{UO}^{2+}+\mathrm{H}_2 \mathrm{O} \rightarrow \mathrm{UO}_2^{2+}+2 \mathrm{H}^{+}+2 e\)

⇒ \(\mathrm{Cr}_2 \mathrm{O}_7^{2-}+14 \mathrm{H}^{+}+6 e \rightarrow 2 \mathrm{Cr}^{3+}+7 \mathrm{H}_2 \mathrm{O}\)

Question 8. Iodine reacts with sodium sulfate, a neutral medium. Write the balanced equation of this reaction. Calculate the equivalent mass of sodium thiosulfate in this reaction. (Assume molecular mass of sodium thiosulfate =M).
Answer:

⇒ \(2 \mathrm{~S}_2 \mathrm{O}_3^{2-}+\mathrm{I}_2 \rightarrow \mathrm{S}_4 \mathrm{O}_6^{2-}+2 \mathrm{I}^{-}\)

Equivalent mass = M.

NCERT Solutions For Class 11 Chemistry Chapter 8 Redox Reactions Long Questions And Answers

Question 1. In the following redox reactions, identify the oxidation half-reactions and reduction half-reactions along with the oxidants and reductants

1. \(\mathrm{Cl}_2(g)+2 \mathrm{I}^{-}(a q) \rightarrow 2 \mathrm{Cl}^{-}(a q)+\mathrm{I}_2(g) \)

2. \( \mathrm{Sn}^{2+}(a q)+2 \mathrm{Fe}^{3+}(a q) \rightarrow \mathrm{Sn}^{4+}(a q)+2 \mathrm{Fe}^{2+}(a q)\)

3. \( 2 \mathrm{Na}_2 \mathrm{~S}_2 \mathrm{O}_3(a q)+\mathrm{I}_2(s) \rightarrow \mathrm{Na}_2 \mathrm{~S}_4 \mathrm{O}_6(a q)+2 \mathrm{NaI}(a q)\)

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4. \(\mathrm{Fe}(s)+2 \mathrm{H}^{+}(a q) \rightarrow \mathrm{Fe}^{2+}(a q)+\mathrm{H}_2(g)\)

5. \( \mathrm{H}_2 \mathrm{~S}(a q)+\mathrm{Cl}_2(g) \rightarrow \mathrm{S}(s)+2 \mathrm{HCl}(a q)\)

6. \(2 \mathrm{FeCl}_2(a q)+\mathrm{Cl}_2(g) \rightarrow 2 \mathrm{FeCl}_3(a q)\)

7. \(2 \mathrm{Hg}^{2+}(a q)+\mathrm{Sn}^{2+}(a q) \rightarrow \mathrm{Hg}_2^{2+}(a q)+\mathrm{Sn}^{4+}(a q)\)

Answer:

1.

Oxidation half-reaction: 2l-(aq)→I₂(s) + 2e

Reduction half-reaction: Cl₂(g) + 2e→2Cl-(aq)

Oxidant: Cl₂(g); Reductant: l-(aq)

2.

Oxidation half-reaction: Sn²⁺(aq)→Sn⁴⁺(aq) + 2e

Reduction half-reaction: Fe³⁺(aq) + e→Fe²⁺(aq)

Oxidant: Fe³⁺(aq); Reductant: Sn2+(aq)

3.

Oxidation half-reaction:\(\mathrm{S}_2 \mathrm{O}_3^{2-}(a q) \rightarrow \mathrm{S}_4 \mathrm{O}_6^{2-}(a q)+2 e\)

Reduction half-reaction: I2(s) + 2e→2l-(aq)

Oxidant: I₂(s); Reductant: Na₂S₂O₃(aq)

4.

Oxidation half-reaction: Fe(s)→Fe²⁺(aq) + 2e

Reduction half-reaction: 2H+(aq) + 2e→H2(g)

Oxidant: H+(aq); Reductant: Fe(s)

Redox Reactions Class 11 Long Questions and Answers

5.

Oxidation half-reaction: S2-(aq)→S(s) + 2e

Reduction half-reaction: Cl₂(g) + 2e→CI-(aq)

Oxidant: Cl₂(g); Reductant: H2S(aq)

6.

Oxidation half-reaction: Fe²⁺(aq)→Fe³⁺(aq)

Reduction half-reaction: Cl₂(g) + 2e→2Cl-(aq)

Oxidant: Cl₂; Reductant: FeCl₂

7.

Oxidation half-reaction: Sn²⁺(aq)→Sn⁴⁺(aq) + 2e

Reduction half-reaction: \(2 \mathrm{Hg}^{2+}(a q)+2 e \rightarrow \mathrm{Hg}_2^{2+}(a q)\)

Oxidant: Hg²⁺(aq); Reductant: Sn²⁺(aq)

Question 2. A compound is composed of three elements A, B, and C. The oxidation numbers of A, B, and C in the compound are +1, +5, and -2, respectively. Which one of the following formulas represents the molecular formula of the compound?

1. A₂BC₄
2. A₂(BC₃)₂.

Answer:

The algebraic sum of the oxidation numbers of all atoms present in a molecule is equal to zero.

In an A₂BC₄ molecule, the algebraic sum ofthe oxidation numbers of all the constituent atoms

= 2 × (+1) +1 × (+5) + 4 × (-2) = -1

In A₂(BC₃)₂ molecule, the algebraic sum of the oxidation numbers of all the atoms

= 2 × (+ 1) + 2[5 + 3 ×  (-2)] = 0

Therefore, A₂(BC₃)₂ represents the molecular formula ofthe compound.

Question 3. Among the reactions given below, identify the redox reactions and also mention the oxidant and the reductant in each case

1. \(\mathrm{Fe}_2 \mathrm{O}_3(\mathrm{~s})+3 \mathrm{CO}(\mathrm{g}) \rightarrow 2 \mathrm{Fe}(\mathrm{s})+3 \mathrm{CO}_2(\mathrm{~g})\)

2. \(2 \mathrm{Na}_2 \mathrm{~S}_2 \mathrm{O}_3(a q)+\mathrm{I}_2(s) \rightarrow \mathrm{Na}_2 \mathrm{~S}_4 \mathrm{O}_6(a q)+2 \mathrm{NaI}(a q)\) →\(\)

3. \(\left(\mathrm{NH}_4\right)_2 \mathrm{~S}(a q)+\mathrm{Cu}\left(\mathrm{NO}_3\right)_2(a q)\) →\(\mathrm{CuS}(s)+2 \mathrm{NH}_4 \mathrm{NO}_3(a q)\)

4. \(\mathrm{Cu}_2 \mathrm{~S}(s)+\mathrm{O}_2(\mathrm{~g}) \rightarrow 2 \mathrm{Cu}(s)+\mathrm{SO}_2(g)\)

5. \(\mathrm{Ca}(\mathrm{OH})_2(a q)+\mathrm{H}_2 \mathrm{SO}_4(a q) \rightarrow \mathrm{CaSO}_4(s)+2 \mathrm{H}_2 \mathrm{O}(l)\)

6. \(\mathrm{H}_2 \mathrm{~S}(g)+\mathrm{HNO}_3(a q)\) →\(\mathrm{H}_2 \mathrm{SO}_4(a q)+\mathrm{NO}_2(g)+\mathrm{H}_2 \mathrm{O}(l)\)

Answer:

1.

The Oxdination number of Fe decreases from +3 to 0 while that of C increases from +2 to +4. so in this reaction, Fe₂O₃ undergoes reduction and Co undergoes Oxdination. Hence, it’s a redox reaction in which Fe₂O₃ acts as an Oxdiant and Co as Reductant.

2.

The oxidation number of S increases from +2 to +2.5 while that of decreases from 0 to -l. So, in this reaction, Na₂S₂O₃ undergoes oxidation and I₂ undergoes reduction. Hence, it is a redox reaction in which Na₂S₂O₃ acts as a reductant and I₂ as an oxidant.

3. In this reaction, there occurs no change in oxidation number for any element. So, it is not a redox reaction.

4.

The oxidation number of Cu decreases from +1 to 0 while that of S increases from -2 to +4. Also, the oxidation number of 0 decreases from O to -2. So, in this reaction, Cu₂S undergoes oxidation as well as reduction and O₂ undergoes reduction. Hence, it is a redox reaction in which Cu₂S serves as both oxidant and reductant and O₂ acts as an oxidant.

5. In this reaction, no change in oxidation number for any element takes place. So, it is not a redox reaction.

6.

The oxidation number of S increases from -2 to +6 while that of N decreases from +5 to +4. So, in this reaction, H₂S undergoes oxidation and HNO₃ undergoes reduction. Hence, it is a redox reaction in which H₂S acts as a reductant and HNO₃ acts as an oxidant

Hence, it is a redox reaction in which H₂S acts as a reductant and HNO₃ acts as an oxidant.

Question 4. Identify the following half-reactions as oxidation half¬ reactions and reduction half-reactions:

1. \(\mathrm{Cr}_2 \mathrm{O}_7^{2-} \rightarrow 2 \mathrm{Cr}^{3+}\)

2. \(\mathrm{Cr}(\mathrm{OH})_4^{-}(a q) \rightarrow \mathrm{CrO}_4^{2-}(a q)\)

3. \(\mathrm{IO}_3^{-}(a q) \rightarrow \mathrm{IO}_4^{-}(a q)\)

4. \(\mathrm{ClO}^{-}(a q) \rightarrow \mathrm{Cl}^{-}(a q)\)

5. \(\mathrm{MnO}_4^{-}(a q) \rightarrow \mathrm{MnO}_2(s)\)

Answer:

1.

The oxidation number of Cr changes from +6 to +3. This indicates that the reaction involves the reduction of Cr₂O₇^-2 Hence, it is a reduction half-reaction.

2.

The reaction involves the oxidation of Cr(OH)₄ because the oxidation number of Cr increases from +3 to +6. So, this reaction represents an oxidation half-reaction.

3.

This reaction represents an oxidation half-reaction since the oxidation number of I increases from +5 to +7 in the reaction.

4.

This reaction represents a reduction half-reaction because the oxidation number of Cl decreases from +1 to -1 in the reaction.

5.

This is a reduction half¬ reaction because the oxidation number of Mn decreases from +7 to +4.

Question 5. Give an example of a disproportionation reaction. Calculate the volume of /0.225(M) KMnO₄ solution that can completely react with 45mL of a 0.125(M) FeSO₄ solution in an acid medium.
Answer:

⇒  \(\left[\mathrm{Fe}^{2+}(a q) \rightarrow \mathrm{Fe}^{3+}(a q)+e\right] \times 5\)

Reduction reaction:

⇒ \(\mathrm{MnO}_4^{-}(a q)+8 \mathrm{H}^{+}(a q)+5 e\) → \(\mathrm{Mn}^{2+}(a q)+4 \mathrm{H}_2 \mathrm{O}(l) \times 1\)

Net reaction:

⇒ \(5 \mathrm{Fe}^{2+}(a q)+\mathrm{MnO}_4^{-}(a q)+8 \mathrm{H}^{+}(a q)\) → \(5 \mathrm{Fe}^{3+}(a q)+\mathrm{Mn}^{2+}(a q)+4 \mathrm{H}_2 \mathrm{O}(l)\)

5 mol of FeSO₄ = 1 mol of MnO₄

or, 1000mL of 5 M FeSO₄ = 1000 ml limit of 1M KMnO₄

or, 1mL of 5M FeSO₄ s lmL of lM KMnO₄

or, 1mL of 1M FeSO₄ \(\equiv \frac{1}{5} \mathrm{~mL}\) of 1M KMno4

or, 45mL of 0.125M FeSO₄ = 45 × 0.125 ,\(\times \frac{1}{5} \mathrm{~mL}\) of 1M KMnO₄ \(\equiv \frac{9 \times 0.125}{0.225} \mathrm{~mL}\) = 5mL of0.225M KMnO₄

= The volume of KMnO₄ required = 5mL

NCERT Class 11 Chemistry Chapter 8 Redox Reactions Long Questions & Answers

Question 6. Identify the following reactions as disproportionation and comproportionation reactions

1. \(\mathrm{Ag}^{2+}(a q)+\mathrm{Ag}(s) \rightarrow 2 \mathrm{Ag}^{+}(a q)\)

2. \(2 \mathrm{H}_2 \mathrm{O}_2(l) \rightarrow 2 \mathrm{H}_2 \mathrm{O}(l)+\mathrm{O}_2(g)\)

3. \({O}(\mathrm{l})+\mathrm{O}_2(\mathrm{~g})\)

4.  \(4 \mathrm{KClO}_3(s) \rightarrow \mathrm{KCl}(s)+3 \mathrm{KClO}_4(s)\) → \(2 \mathrm{MnO}_4^{-}(a q)+\mathrm{MnO}_2(s)+4 \mathrm{OH}^{-}(a q)\)

5. \(2 \mathrm{NH}_4 \mathrm{NO}_3(s) \rightarrow \mathrm{N}_2(g)+4 \mathrm{H}_2 \mathrm{O}(g)+\mathrm{O}_2(g)\)

6. \(\mathrm{IO}_3^{-}(a q)+5 \mathrm{I}^{-}(a q)+6 \mathrm{H}^{+}(a q) \rightarrow 3 \mathrm{I}_2(s)+3 \mathrm{H}_2 \mathrm{O}(l)\)

Answer:

1.

In this reaction, the resulting species, Ag+, exists in an oxidation state (+1) that lies between the oxidation states of Ag²⁺(+2) and Ag(0). Hence, it is a comproportionation reaction.

2.

In this reaction, H₂O₂ (oxidation number of 0 is -1 ) decomposes to form H₂O (oxidation number of O is -2) and O₂ (oxidation number of O is zero).

The oxidation state -1 lies between 0 and -2. So, this reaction represents a disproportionation reaction.

3.

In this reaction, the oxidation number of Cl decreases (+5 to-1 ) as well as increases (+5 to +7). This means KClO₃ undergoes both oxidation and reduction in the reaction. Hence, this reaction is a disproportionation reaction.

4.

In this reaction, the oxidation number of Mn increases (+6 to +7) and decreases (+6 to +4) as well. ‘Hus’ means MnO^– undergoes both oxidation and reduction in the reaction. Therefore, this reaction is a disproportionation reaction.

5.

NH₄NO₃ molecule has two N-atoms, out of which one has an oxidation number of -3 and the other has an oxidation number of +5—the decomposition of NH₄NO₃ results in N₂(g).

So, in this reaction, the oxidation number of one N-atom increases from -3 to 0 while the oxidation number of other N-atom decreases from +5 to 0. Since the oxidation number 0 lies between the oxidation numbers -3 and +5, the reaction represents a comproportionation reaction.

6.

In this reaction, 10J (oxidation number of I = +5) reacts with I- (oxidation number of = -1 ) to form I₂ (oxidation number of = 0 ). Since the oxidation number 0 lies between -1 and +5, the reaction represents a comproportionation reaction.

Question 7. Determine the equivalent masses of the following underlined compounds by both oxidation number and electronic methods

1. SO₂ + 2H₂O→H₂SO₄

2. HNO₃→NO₂ + H₂O

3. HNO₃ + 3H⁺→ NO + 2H₂O

4. MnO₂ + 4H⁺→ Mn²⁺→ + 2H₂O

5.  \(\mathrm{KMnO}_4+\mathrm{FeSO}_4+\mathrm{H}_2 \mathrm{SO}_4\) → \(\mathrm{K}_2 \mathrm{SO}_4+\mathrm{MnSO}_4+\mathrm{Fe}_2\left(\mathrm{SO}_4\right)_3+\mathrm{H}_2 \mathrm{O}\)

Answer:

1. Oxidation number method: \(\stackrel{+4}{\mathrm{SO}_2}+2 \mathrm{H}_2 \mathrm{O} \rightarrow \mathrm{H}_2 \mathrm{SO}_4\)

In this reaction, the oxidation number of S increases from +4 to +6. The change in oxidation number per molecule of SO₂ = 6 – 4

= 2 units.

∴ Equivalent mass of SO₂

⇒ \(\frac{\text { Molecular mass of } \mathrm{SO}_2}{2}=\frac{64}{2}=32\)

Electronic method: SO, + 2H₂O→4H⁺+ SO₄ ^2-+ 2e

Number of electrons lost by a molecule of SO₂ for its oxidation = 2.

∴ Equivalent mass of SO₂ \(=\frac{64}{2}=32\)

Class 11 Chemistry Chapter 8 Redox Reactions NCERT Long Questions

2. Oxidation number method: \(\stackrel{+5}{\mathrm{HN}} \mathrm{O}_3 \rightarrow \stackrel{+4}{\mathrm{~N}} \mathrm{O}_2+\mathrm{H}_2 \mathrm{O}\)

The change in oxidation number per molecule of HNO₃ = 5-4 = unit:

∴ Equivalent mass of HNO₃

⇒ \(\frac{\text { Molecular mass of } \mathrm{HNO}_3}{1}=\frac{63}{1}=63\)

Electronic method: NO^–₃ + 2H⁺ + e→ NO₂+ H₂O.

The number of electrons involved in the die reduction of NO^–₃ is 1.

∴ Equivalent mass of HNO₃

⇒ c\(\frac{\text { Molecular mass of } \mathrm{HNO}_3}{1}=\frac{63}{1}=63\)

3. Oxidation number method: \(\mathrm{H}^{+5} \mathrm{~S}_3+3 \mathrm{H}^{+} \rightarrow \stackrel{+2}{\mathrm{~N} O}+2 \mathrm{H}_2 \mathrm{O}\)

In this reaction, the oxidation number of N decreases from +5 to +2. So, the change in oxidation number per molecule of HNO₃ = 5-2

= 3 units.

∴ Equivalent mass of HNO₃

⇒ \(=\frac{\text { Molecular mass of } \mathrm{HNO}_3}{1}=\frac{63}{3}=21\)

Electronic method:  \(\mathrm{NO}_3^{-}+4 \mathrm{H}^{+}+3 e \rightarrow \mathrm{NO}+2 \mathrm{H}_2 \mathrm{O}\)

The number of electrons involved in the reduction of 1 molecule of HNOg = 3

∴ Equivalent mass of HNO₃

⇒ \(\frac{\text { Molecular mass of } \mathrm{HNO}_3}{1}=\frac{63}{3}=21\)

4. Oxidation number method: \(\stackrel{+4}{\mathrm{MnO}_2}+4 \mathrm{H}^{+} \rightarrow \stackrel{+2}{\mathrm{M}}{ }^{2+}+2 \mathrm{H}_2 \mathrm{O}\)

In this reaction, the oxidation number decreases from +4 to +2. So, the change in oxidation number per molecule of MnO₂ = 4-2

= 2 units.

∴  Equivalent mass of MnO₂

⇒ \(=\frac{\text { Molecular mass of } \mathrm{MNO}_2}{1}=\frac{87}{2}=43.5\)

  Electronic method: \(\mathrm{MnO}_2+4 \mathrm{H}^{+}+2 e \rightarrow \mathrm{Mn}^{2+}+2 \mathrm{H}_2 \mathrm{O}\)

The number of electrons involved in the reduction of a molecule of MnO₂ =-2

⇒ \(=\frac{\text { Molecular mass of } \mathrm{MnO}_2}{1}=\frac{87}{2}=43.5\)

5. Oxidation number method:

⇒ \(\stackrel{+7}{\mathrm{~K}} \mathrm{nO}_4+\stackrel{+2}{\mathrm{~F}} \mathrm{eSO}_4+\mathrm{H}_2 \mathrm{SO}_4\)

⇒ \(\mathrm{~K}_2 \mathrm{SO}_4+\stackrel{+2}{\mathrm{MnSO}_4+\stackrel{+3}{\mathrm{Fe}} \mathrm{e}_2}\left(\mathrm{SO}_4\right)_3+\mathrm{H}_2 \mathrm{O}\)

In this reaction, KMnO₄ undergoes reduction because the oxidation number of Mn decreases from +7 to +2. So, the change in oxidation number of Mn= 7-2

=5 units.

∴  Equivalent mass of KMnO₄

⇒ \(\frac{\text { Molecular mass of } \mathrm{KMnO}_4}{\begin{array}{c}
\text { Change in oxidation number per molecule } \\
\text { of } \mathrm{KMnO}_4 \text { because of its reduction }
\end{array}}\)

⇒  \(\frac{158}{5}\)

= 31.6

In the reaction, FeSO₄ undergoes oxidation because the oxidation number of Fe increases from +2 to +3. So, the change in oxidation number of Fe = 3-2

= 1 unit.

∴  Equivalent mass of FeSO₄

⇒ \(\frac{\text { Molecular mass of } \mathrm{FeSO}_4}{\begin{array}{c}
\text { Change in oxidation number per molecule } \\
\text { of } \mathrm{FeSO}_4 \text { because of its oxidation }
\end{array}}\)

⇒ \(\frac{151. 85}{1}\)

= 151.85

∴  Electronic method:

MnO₄ + 8H⁺+ 5e→ Mn²⁺  + 4H₂O

Equivalent mass of KMnO₄

⇒ \(=\frac{\text { Molecular mass of } \mathrm{KMnO}_4}{\begin{array}{c}
\text { Number of electrons gained in reduction of } \\
\text { one molecule of } \mathrm{KMnO}_4
\end{array}}\)

=  \(\frac{158}{5}\)

31.6

Fe²⁺ →Fe³⁺ + e

∴  Equivalent mass of FeSO₄

⇒ \(=\frac{\text { Molecular mass of } \mathrm{FeSO}_4}{\begin{array}{c}
\text { Number of electrons lost in oxidation of } \\
\text { one molecule of } \mathrm{FeSO}_4
\end{array}}\)

=\(\frac{151.85}{1}\)

Question 8. Determine the equivalent mass of Br₂(l) [Molecular mass =159.82 in the given reaction:

⇒ \(2 \mathrm{MnO}_4^{-}(a q)+8 \mathrm{H}^{+}(a q)+\mathrm{Br}_2(l)\)→ \(2 \mathrm{Mn}^{2+}(a q)+2 \mathrm{BrO}_3^{-}(a q)+2 \mathrm{H}_2 \mathrm{O}(l)\)

In the given reaction, the oxidation half-reaction is —

⇒ \(\mathrm{Br}_2(l)+6 \mathrm{H}_2 \mathrm{O}(l) \rightarrow 2 \mathrm{BrO}_3^{-}(a q)+12 \mathrm{H}^{+}(a q)+10 e\)

The number of electrons involved in the oxidation of one molecule of Br₂ = 10 Equivalent mass of Br₂.

⇒ \(=\frac{\text { Molecular mass of } \mathrm{Br}_2}{\begin{array}{c}
\text { Number of electrons involved per } \\
\text { molecule of } \mathrm{Br}_2 \text { in its oxidation }
\end{array}}\)

=\(\frac{159.82}{10}\)

= 15.982

Question 9. \(\mathrm{MnO}_4^{2-}\) undergoes a disproportionation reaction in an acidic medium but MnO₄ docs do not. Give reason.
Answer:

The oxidation number of Mn in MnO₄ is +7, which is the highest oxidation number that Mn can possess. So, it does not undergo the disproportionation reaction.

Again, in the case of \(\mathrm{MnO}_4^{2-}\) the oxidation number of Mn is +6. Therefore, Mn in \(\mathrm{MnO}_4^{2-}\) can increase its oxidation number to +7 or decrease it to some lower value. So, \(\mathrm{MnO}_4^{2-}\) undergoes a disproportionation reaction as given below—

In the above reaction, the oxidation number of Mn increases from +6 in \(\mathrm{MnO}_4^{2-}\) to +7 in MnO₄ and decreases to +4 in MnO₄.

Question 10. What amount of K₂Cr₂O₇? (in mmol) is required to oxidize 24 mL 0.5 M Mohr’s salt?
Answer:

The number of mmol of Mohr’s salt in 24 mL 0.5MMohr’s salt solution =24 x 0.5 = 12.

So, the balanced redox reaction is

⇒ \(\mathrm{K}_2 \mathrm{Cr}_2 \mathrm{O}_7+6\left(\mathrm{NH}_4\right)_2 \mathrm{SO}_4 \cdot \mathrm{FeSO}_4 \cdot 6 \mathrm{H}_2 \mathrm{O}+7 \mathrm{H}_2 \mathrm{SO}_4\)

⇒ \(\mathrm{~K}_2 \mathrm{SO}_4+6\left(\mathrm{NH}_4\right)_2 \mathrm{SO}_4+3 \mathrm{Fe}_2\left(\mathrm{SO}_4\right)_3+\mathrm{Cr}_2\left(\mathrm{SO}_4\right)_3+43 \mathrm{H}_2 \mathrm{O}\)

So, from the balanced equation, we see that 6mmol Mohr’s salt gets oxidized by 1mmol K₂Cr₂O₇.

12 mmol Mohr’s salt gets oxidized by \(\frac{1}{6} \times 12\) = 2 mmol K₂Cr₂O₇.

Question 11. Explain with reaction mechanism why the reaction between 03 and H₂O₂ is written as—

⇒ \(\mathrm{O}_3(\mathrm{~g})+\mathrm{H}_2 \mathrm{O}_2(l) \rightarrow \mathrm{H}_2 \mathrm{O}(l)+\mathrm{O}_2(\mathrm{~g})+\mathrm{O}_2(\mathrm{~g})\)

Answer:

The reaction between O₃ and H₂O₂ is as follows

First step: O₃(g)→O₂(g) + O(g)’

Second step: H₂O₂(g) + O(g)→H₂O(g) +O₂(g)

In the first step, ozone produces nascent oxygen which is H₂O₂ in the second step. So, the overall reaction is as follows H₂O₂ + O₃→H₂O + O₂ + O₂

So, in the overall reaction, O₂ Is written twice because a total of two molecules of O₂ are produced during the reaction.

Question 12. 12.53 cm3 0.051M SeO₂ reacts completely with 25.5 cm3 0.1 M CrSO₄ to produce Cr₂(SO₄)₃. What is the change in the oxidation number of Se in this redox reaction?
Answer:

Let the oxidation number of Se in the newly produced compound be x.

The redox reaction is as follows:

⇒ \({\left[\mathrm{Se}^{4+}+x e \longrightarrow \mathrm{Se}^{4-x}\right] \times 1}\)

⇒\({\left[\mathrm{Cr}^{2+} \longrightarrow \mathrm{Cr}^{3+}+e\right] \times x}\)

⇒ \(\mathrm{Se}^{4+}+x \mathrm{Cr}^{2+} \longrightarrow \mathrm{Se}^{4-x}+x \mathrm{Cr}^{3+}\)

Now, 12.53 cm3 0.051M SeO₂ = 12.53 x 0.051 = 0.64 mmol SeO₂

25.5 cm3 0.1 M CrSO₄= 25.5 ×  0.1 = 2.55 mmol CrSO₄ However according to the balanced equation, 1 mol SeO₂ gets reduced by x mol CrSO₄.

2.55 mmol CrSO₄ is reduced by \(\frac{2.55}{x}\) mmol SeO₂

But 0.64 mmol SeO₂ gets reduced

⇒ \(\text { So, } \frac{2.55}{x}=0.64 \quad \text { or, } x=4\)

The change in oxidation number of Se -atom = 4- (4- x) = x = 4.

Question 13. 30 ml 0.05 M KMnb4 is required for the complete oxidation of 0.5 g oxalate in an acidic medium. Calculate ) tl,e percent amount of oxalate in that salt sample:
Answer:

⇒ \(2 \mathrm{MnO}_4^{-}+5 \mathrm{C}_2 \mathrm{O}_4^{2-}+16 \mathrm{H}^{+} \rightarrow 2 \mathrm{Mn}^{2+}+10 \mathrm{CO}_2+8 \mathrm{H}_2 \mathrm{O}\)

According to the equation, 2 mol MnO-4 = 5 mol C₂O₄

⇒ \(1 \mathrm{~mol} \mathrm{MnO}_4^{-} \equiv \frac{5}{2} \mathrm{~mol} \mathrm{C}_2 \mathrm{O}_4^{2 \mathrm{ris}}\)

Again, 1000 mL 0.05(M)KMnO4 =→ 0.05 mol KMnO₄

30 mL 0.05(M)MnO4 \(\Rightarrow \frac{0.05 \times 30}{1000}\)

= 1.5×10-3 mol KMnO₄

Now, 1 mol \(\mathrm{MnO}_4=\frac{5}{2} \mathrm{~mol} \mathrm{C}_2 \mathrm{O}_4\)

⇒ \(1.5 \times 10^{-3} \mathrm{~mol} \mathrm{MnO}_4=\frac{5}{2} \times 1.5 \times 10^{-3} \mathrm{~mol} \mathrm{C}_2 \mathrm{O}_4^2\)

⇒ \(=\frac{5}{2} \times 1.5 \times 10^{-3} \times 38 \mathrm{~g} \mathrm{C}_2 \mathrm{O}_4^{2-}=0.33 \mathrm{~g} \mathrm{C}_2 \mathrm{O}_4^{2-}\)

⇒ \(\text { Percentage of } \mathrm{C}_2 \mathrm{O}_4^{2-} \text { in the sample }=\frac{0.33 \times 100}{0.5}=66 \%\)

Long Answer Questions for Redox Reactions Class 11 Chemistry

Question 14. What will be the nature of the suit formed when 2 mol Nil Is added to the pigeon’s solution of mol pyrophosphoric? Clive equation?

Answer:

From the structure of pyrophosphoric acid, it Is clear that it contains four replaceable hydrogen atoms.

So, the reaction between and 2 mol NaOH will be as follows:

⇒ \(-\mathrm{H}_4 \mathrm{P}_2 \mathrm{O}_7+2 \mathrm{NaOH} \rightarrow \mathrm{Na}_2 \mathrm{H}_2 \mathrm{P}_2 \mathrm{O}_7+2 \mathrm{H}_2 \mathrm{O}\)

There are two replaceable 11-atoms in Na₂H₂P₂O₇ fonned due to the above reaction. So, it is an acidic salt.

Question 15. Oxidation million of the elements A, It mid-C are 12,1 to mid -2 respectively. Which one will lie the formula of the compound containing these three elements?

⇒ \(\mathrm{A}_2\left(\mathrm{BC}_2\right)_2, \mathrm{~A}_3\left(\mathrm{~B}_2 \mathrm{C}\right)_2, \mathrm{~A}_3\left(\mathrm{BC}_4\right)_2\)

Answer:

The total oxidation number of all the elements in a compound should be zero (0).

In A₂(BC₂) molecule, the sum of oxidation numbers of all the atoms

=2 ×(+ 2) + 2 × (+ 5) + 4 × (-2) = + 6

In the A₂(B₂C)₂ molecule, the sum of oxidation numbers of all the atoms

= 3 × (+ 2) + 4 × (+ 5) + 2 × (-2) = + 22

In A₃(BC₄)₂ molecule, the sum of oxidation numbers of all the atoms

= 3 × (+ 2) + 2 × (+ 5) + 8 ×(-2) = 0.

∴ The correct formula of the compound will be A₃(BC₄)₂

Question 16. In an acidic medium, for the reduction of each NO₃ ion in the given reaction, how many electrons will be required? NO₃ NH₂OH
Answer:

NO₃— NH₂OH; For equalizing the number of O -atoms on both sides, two H₂O molecules are added to the right side (having a lesser number of O -atoms) and two H+ ions are added to the left side for each molecule of H₂O added.

⇒ \(\mathrm{NO}_3^{-}+4 \mathrm{H}^{+} \longrightarrow \mathrm{NH}_2 \mathrm{OH}+2 \mathrm{H}_2 \mathrm{O}\)

For equalizing the number of H -atoms on both sides, three additional H+ ions are required on the left side

so we get, \(\mathrm{NO}_3^{-}+7 \mathrm{H}^{+} \longrightarrow \mathrm{NH}_2 \mathrm{OH}+2 \mathrm{H}_2 \mathrm{O}\)

To balance the charge on both sides, 6 electrons are added to the left side ofthe equation.

⇒ \(\mathrm{NO}_3^{-}+7 \mathrm{H}^{+}+6 e \longrightarrow \mathrm{NH}_2 \mathrm{OH}+2 \mathrm{H}_2 \mathrm{O}\)

Hence, for the reduction of each NO₃ ion into an NH₂OH molecule, 6 electrons are required.

Question 17. Identify the redox reactions among the following:

1. 2CuSO₄ + 4KI→2CuI + I₂ + 2K₂SO₄

2. BaCl₂ + Na₂SO₄→BaSO₄ + 2NaCl

3. 2NaBr + Cl₂→2NaCl + Br₂

4. NH₄NO₂→+N₂ + 2H₂O

5. CuSO₄ + 4NH₃→[Cu(NH₃)₄]SO₄

6. 3I₂ + 6NaOH→NaIO₃ + 5NaI + 3H₂O

Answer:

In this reaction, the oxidation number of Cu decreases (+ 2 → +1) and the oxidation number of I₄ increases (-1→ 0) i.e. reduction of CuSO₄ and oxidation of KI take place. Thus, it is a redox reaction.

1.  \(\stackrel{+2}{\mathrm{CuSO}_4}+\stackrel{-1}{\mathrm{KI}} \rightarrow \stackrel{+1}{\mathrm{CuI}}+\stackrel{0}{\mathrm{I}} 2+\mathrm{K}_2 \mathrm{SO}_4\)

This reaction does not involve any change in the oxidation number of any element i.e., in this reaction, oxidation or reduction does not take place. Hence, it is not a redox reaction

2.  \(\stackrel{+2}{\mathrm{BaCl}_2}+\stackrel{+1}{\mathrm{Na}_2} \mathrm{SO}_4 \rightarrow \stackrel{+2}{\mathrm{BaSO}}{ }_4+2 \mathrm{NaCl}^{-1}\)

In this reaction, the oxidation number of bromine increases from -1 to 0 and the oxidation number of chlorine decreases from 0 to -1. In this case, NaBr gets oxidized whereas Cl₂ gets reduced. Hence, this reaction is a redox reaction.

3. \(2 \mathrm{NaBr}+\stackrel{0}{\mathrm{C}} \mathrm{l}_2 \rightarrow 2 \mathrm{Na}{ }^{-1} \mathrm{Cl}+\stackrel{0}{\mathrm{Br}}{ }_2\)

In NH₄NO₂, the oxidation number of N in NH₄ increases from -3 to 0, while the oxidation number of N in NO₂ decreases from +3 to 0, i.e., in this reaction, simultaneous oxidation of NH+ and reduction of NO₂ in the compound occur. So, this reaction is a redox reaction.

4. \(\stackrel{-3}{\mathrm{NH}_4}{\stackrel{+3}{\mathrm{~N}} \mathrm{O}_2 \rightarrow \stackrel{0}{\mathrm{~N}}}_2+2 \mathrm{H}_2 \mathrm{O}\)

This reaction does not involve any change in the oxidation number of any element. So, it is not a redox reaction.

5.  \(\left(\stackrel{+2}{\mathrm{CuSO}_4}+4 \mathrm{NH}_3\right) \rightarrow\left[\stackrel{+2}{\mathrm{Cu}}\left(\mathrm{NH}_3\right)_4\right] \mathrm{SO}_4\)

In the given reaction, the oxidation number of iodine increases from 0 to +5 and decreases from 0 to -1 i.e., both oxidation and reduction occur in this reaction. Thus, it is a redox reaction.

6. \(3 \stackrel{0}{\mathrm{I}}_2+6 \mathrm{NaOH} \rightarrow \mathrm{NaIO}_3^{+5}+5 \mathrm{NaI}^{-1}+3 \mathrm{H}_2 \mathrm{O}\)

Question 18. Which of the following reactions are disproportionation reactions and comproportionation reactions?

1. 4KClO₃→KCl + 3KClO₄

2. 3K₂MnO₄ + 2H₂O→2KMnO₄ + MnO₂ + 4KOH

3. KIO₃ + 5KI + 6HCI→3I₂ + 6KCI + 3H₂O

4. 2C₆H₅CHO + NaOH C₆H₅COONa + C₆H₅CH₂OH

5. Ag²⁺ + Ag→2Ag⁺

Answer:

1.

In KClO₃, the oxidation number of Cl = + 5. The oxidation numbers of Cl in KCl and KClO₄ are -1 and + 7 respectively. So in this reaction, KClO₃ undergoes simultaneous oxidation and reduction producing KClO₄ and KCl respectively. Hence, it is a disproportionation reaction.

2.

The oxidation number of Mn in K₂MnO₄ = + 6. On the other hand, the oxidation numbers of Mn in the products KMnO₄ and MnOa are + 7 and + 4 respectively. Therefore, in the reaction, K₂MnO₄ is oxidized and reduced at the same time forming KMnO₄ and MnO₄. Thus, it is a disproportionation reaction.

3.

The oxidation numbers of iodine in KIO₃ and KI are + 5 and -1 respectively and the oxidation number of iodine in 12 is zero. This oxidation number lies between + 5 and -1, which is an intermediate oxidation state. So, it is a comproportionation reaction.

4.

In this reaction, the oxidation number of carbon in the benzene ring does not change. However, the oxidation number of carbon atoms in the —CHO group (the oxidation number of carbon in —CHO is +1 ) changes to a higher oxidation number of +3 in the —COONa group and a lower oxidation number of -1 in the —CH₂OH group. Here, —the CHO group gets simultaneously oxidized & reduced. Hence, it is a disproportionation reaction.

5.

The oxidation numbers of the reactants Ag²⁺ and Ag are + 2 and O respectively and the oxidation number of the product is +1. This oxidation number is intermediate between the oxidation numbers +2 and O . so it is a comproportionation reaction.

Question 19. Identify the redox reaction(s) and also the oxidants B and the reductants from the following reaction(s).

1. \(2 \mathrm{MnO}_4^{-}+5 \mathrm{SO}_2+6 \mathrm{H}_2 \mathrm{O}\) → \( 5 \mathrm{SO}_4^{2-}+2 \mathrm{Mn}^{2+}+4 \mathrm{H}_3 \mathrm{O}^{+} \)

2. \(\mathrm{NH}_4^{+}+\mathrm{PO}_4^{3-} \longrightarrow \mathrm{NH}_3+\mathrm{HPO}_4^{2-} \)

3. \( \mathrm{HClO}+\mathrm{H}_2 \mathrm{~S} \longrightarrow \mathrm{H}_3 \mathrm{O}^{+}+\mathrm{Cl}^{-}+\mathrm{S}\)

Answer:

In this reaction, the oxidation number of Mn decreases from (+7→+2) and the oxidation number of S increases from (+4→+6). So this reaction causes a reduction of MnO₄ and oxidation of SO₂. Hence, the reaction is a redox reaction. Here Mnt)ÿ acts as an oxidant and SO₂ as a reductant.

This reaction does not involve any change in the oxidation number of any element. So it is, not a redox reaction.

This reaction involves an increase in the oxidation number of S from -2 to 0, and a decrease in the oxidation number of, Cl from +1 to -1. So it is a redox reaction. Here HCIO is an oxidising agent and H₂S is a reducing agent.

Question 20. Determine the equivalent masses of Na₂S₂O₃.5H₂O +2 and KBrO₃ In the following reactions.

⇒ \(2 \mathrm{~S}_2 \mathrm{O}_3^{2-}+\mathrm{I}_2 \rightarrow \mathrm{S}_4 \mathrm{O}_6^{2-}+2 \mathrm{I}^{-}\)

⇒ \(\mathrm{BrO}_3^{-}+6 \mathrm{H}^{+}+6 e \longrightarrow \mathrm{Br}^{-}+3 \mathrm{H}_2 \mathrm{O}\)

Answer:

In this reaction, two \(\mathrm{S}_2 \mathrm{O}_3^{2-}\) ions are oxidised by losing 2 electrons. So, for the oxidation of one \(\mathrm{S}_2 \mathrm{O}_3^{2-}\) ion, one electron is given up

Equivalent mass of Na₂S₂O₃.5H₂O

⇒ \(=\frac{\text { Molecular mass of } \mathrm{Na}_2 \mathrm{~S}_2 \mathrm{O}_3 \cdot 5 \mathrm{H}_2 \mathrm{O}}{1}=248\)

This reaction produces Br- from BrO₃. In the reduction of each molecule of KBr03, 6 electrons are accepted.

In the given reaction, the equivalent mass of KBrO₃

⇒ \(\frac{\text { Molecular mass of } \mathrm{KBrO}_3}{6}=\frac{167}{6}=27.8\)

NCERT Solutions Class 11 Chemistry Chapter 8 Long Questions & Answers

Question 21. Determine the equivalent weights of the underlined compounds in the following two reactions:

1. \(\mathrm{FeSO}_4+\mathrm{KMnO}_4+\mathrm{H}_2 \mathrm{SO}_4\)

→ \(\mathrm{K}_2 \mathrm{SO}_4+\mathrm{MnSO}_4+\mathrm{Fe}_2\left(\mathrm{SO}_4\right)_3+\mathrm{H}_2 \mathrm{O}\)

2. MnO₂+HCl  → MnCl₂+ Cl₂+H₂O

K = 39, Mn = 55, O = 16

Answer:

In this reaction, the decrease in oxidation number of Mn =(7-2) = 5 units. Equivalent weight of Mn.

1.  \(\frac{\text { Molecular weight of } \mathrm{KMnO}_4}{\text { Change in oxidation number }}\)

= \(\frac{158}{5}\)

= 31.6

⇒ \(\stackrel{+4}{\mathrm{MnO}}{ }_2 \longrightarrow \stackrel{+2}{\mathrm{MnCl}}{ }_2\)

Here the oxidation number of Mn decreases by (4-2)

= 2 unit.

∴ Equivalent weight of MnO₂

⇒ \(=\frac{\text { Molecular weight of } \mathrm{MnO}_2}{\text { Change in oxidation number }}=\frac{87}{2}=43.5\)

Question 22. Balance the following equation with the help of the oxidation number method.

⇒ \(\mathrm{Fe}_3 \mathrm{O}_4+\mathrm{CO} \rightarrow \mathrm{FeO}+\mathrm{CO}_2\)

Answer:

In Fe3O₄, the oxidation number of each Fe -atom =+2.67. In the reaction, the oxidation number of each Fe -atom decreases from + 2.67 to 2. So, decrease in oxidation number. of eachFe -atom = +0.67

Therefore for three Fe -atoms, the total decrease in oxidation number 3 × (+ 0.67) =+ 2 unit.

On the other hand, the oxidation number of C increases from +2 to +4. Hence, an increase in the oxidation number of C= 2 units.

Therefore, in the reaction, Fe₃O4 and CO will react with each other in the molar ratio of 2: 2 or 1: 1 .

Again 1 molecule of Fe₃O₄ will produce 3 molecules of F₂O. Hence, the balance equation will be

Fe₃O₄ + CO → 3FeO + CO₂.

Question 23. Balance by ion-electron method: MnO₂ + HCl→+Mn²⁺ + Cl₂ + H₂O
Answer:

Or MnO₂ + 4H⁺ + 4Cl→ Mn²⁺ + 2Cl + Cl₂+ 2H₂O

Therefore the balanced chemical equation is:

MnO₂ + 4H +  4Cl → MnCl₂ + Cl₂ + 2H₂O

Question 24. In a basic medium, balance the half-reactions below:

1. \(\mathrm{Cr}(\mathrm{OH})_3 \rightarrow \mathrm{CrO}_4^{2-}\)
2. \(\mathrm{Cl}_2 \mathrm{O}_7 \rightarrow 2 \mathrm{ClO}_2^{-}\)

Answer:

In order to equalize the number of O -atoms, one H₂O molecule is added to the right side (because it has an excess O -atom) and for this 1 molecule of H₂O, two OH Now, we get Cr(OH)₂ + 2OH^– ions are added to the left side. CrO^2- +H₂O. In this equation, five H -atoms are on the left side, and two H atoms are present on the right side. To equalize the number of H -atoms on both sides, three OH-(aq) and three H₂O molecules are added to the left side and right side respectively. Finally, we get

⇒ \( \mathrm{Cr}(\mathrm{OH})_3+2 \mathrm{OH}^{-}+3 \mathrm{OH}^{-} \rightarrow \mathrm{CrO}_4^{2-}+\mathrm{H}_2 \mathrm{O}+3 \mathrm{H}_2 \mathrm{O}\)

Or, \(\mathrm{Cr}(\mathrm{OH})_3+5 \mathrm{OH}^{-} \longrightarrow \mathrm{CrO}_4^{2-}+4 \mathrm{H}_2 \mathrm{O}\)

For balancing the charge, 3 electrons are added to the right side. Therefore, the final half-reaction becomes,

⇒ \(\mathrm{Cr}(\mathrm{OH})_3+5 \mathrm{OH}^{-} \longrightarrow \mathrm{CrO}_4^{2-}+4 \mathrm{H}_2 \mathrm{O}+3 e\)

2. To balance the number of 0 -atoms on both sides, 3 molecules of H₂O(Z) are added to the left side (because there are excess O -atoms on this side) and for these three H₂O(l) molecules, six OH- (aq) ions are added to the right side. Then we get

⇒ \(\mathrm{Cl}_2 \mathrm{O}_7+3 \mathrm{H}_2 \mathrm{O} \longrightarrow 2 \mathrm{ClO}_2^{-}+6 \mathrm{OH}^{-}\)

To balance the charge, electrons are added to the left side. Hence, the balanced equation is

⇒ \(\mathrm{Cl}_2 \mathrm{O}_7+3 \mathrm{H}_2 \mathrm{O}+8 e \longrightarrow 2 \mathrm{ClO}_2^{-}+6 \mathrm{OH}^{-}\)

Question 25. Balance the following reaction in acidic and alkaline medium: \(\mathrm{SO}_3^{2-}(a q) \longrightarrow \mathrm{SO}_4^{2-}(a q)\) 
Answer:

Addlemedium:

⇒ \(\mathrm{SO}_3^{2-}(a q) \longrightarrow \mathrm{SO}_4^{2-}(a q)\)

In Tills reaction, this left side of the equation is deficient in one () -atom. So the number of O -atoms on both sides is equalized by adding one H2O(aq) molecule to the left side.

⇒ \(\mathrm{SO}_3^{2-}(a q)+\mathrm{H}_2 \mathrm{O}(l) \longrightarrow \mathrm{SO}_4^{2-}(a q)\)

To equalize the number of H -atoms on both sides, two H+ ions are added to the right side. So we get—

⇒ \(\mathrm{SO}_3^{2-}(a q)+\mathrm{H}_2 \mathrm{O}(l) \longrightarrow \mathrm{SO}_4^{2-}(a q)+2 \mathrm{H}^{+}(a q)\)

To balance the charge on both sides, 2 electrons are added to the right side, we get—

⇒ \(\mathrm{SO}_3^{2-}(a q)+\mathrm{H}_2 \mathrm{O}(l) \longrightarrow \mathrm{SO}_4^{2-}(a q)+2 \mathrm{H}^{+}(a q)+2 e\)

Basic medium: \(\mathrm{SO}_3^{2-}(a q) \longrightarrow \mathrm{SO}_4^{2-}(a q)\)

To balance the number of O -atoms on both sides, two OH”(a<7) ions and one H20(Z) molecule are added to the left side and right side respectively. This gives—

⇒ \(\mathrm{SO}_3^{2-}(a q)+2 \mathrm{OH}^{-}(a q) \longrightarrow \mathrm{SO}_4^{2-}(a q)+\mathrm{H}_2 \mathrm{O}(l)\)

To balance the change on both sides, we add 2 electrons to the right side. Thus, the balance equation is—

⇒ \(\mathrm{SO}_3^{2-}(a q)+2 \mathrm{OH}^{-}(a q) \longrightarrow \mathrm{SO}_4^{2-}(a q)+\mathrm{H}_2 \mathrm{O}(l)+2 e\)

Question 26. Determine the values of x and y in the following balanced equation:

⇒ \(5 \mathrm{H}_2 \mathrm{O}_2+x \mathrm{ClO}_2+2 \mathrm{OH}^{-} \longrightarrow x \mathrm{Cl}^{-}+y \mathrm{O}_2+6 \mathrm{H}_2 \mathrm{O}\) 
Answer:

Oxidation half-reaction:

⇒  \(\mathrm{H}_2 \mathrm{O}_2+2 \mathrm{OH}^{-} \longrightarrow \mathrm{O}_2+2 \mathrm{H}_2 \mathrm{O}+2 e\)……………………….(1)

Reduction half-reaction:

⇒\(\mathrm{ClO}_2+2 \mathrm{H}_2 \mathrm{O}+5 e \longrightarrow \mathrm{Cl}^{-}+4 \mathrm{OH}^{-}\) ……………………….(2)

Multiplying equations (1) and (2) by 5 and 2 respectively and adding the equations, we get—

⇒ \(5 \mathrm{H}_2 \mathrm{O}_2+10 \mathrm{OH}^{-}+2 \mathrm{ClO}_2+4 \mathrm{H}_2 \mathrm{O}\)→ \(2 \mathrm{Cl}^{-}+5 \mathrm{O}_2+10 \mathrm{H}_2 \mathrm{O}+8 \mathrm{OH}^{-}\)

∴ 5H₂O₂ + 2ClO₂ + 2OH^–→2Cl^–+ 5HO₂ + 6H₂O ……………………….(3)

Comparing equation (3) with the given equation, we get x = 2 and y – 5.

Question 27. In the given reaction determine the equivalent weight of AS₂S₃:
Answer:

⇒ \(\mathrm{As}_2 \mathrm{~S}_3+7 \mathrm{ClO}_3^{-}+7 \mathrm{OH}^{-}-7\) → \(2 \mathrm{AsO}_4^{3-}+7 \mathrm{ClO}^{-}+3 \mathrm{SO}_4^{2-}+6 \mathrm{H}_2 \mathrm{O}\)

The increase in oxidation number of each As -atom =5-3 = 2 units.

So, the total increase in oxidation number of two As -atoms = 2 ×2

= 4 units.

Two increases in the oxidation number of each S-atom =+6-(-2)

Therefore, the total Increase in oxidation number of three S -atoms = 3 × 8

= 24 units.

Hence, the total Increase In oxidation number for each As 2S,t molecule In Its oxidation Is a (24 + 4) = 20 unit.

Equivalent weight of AS₂S₃ In the given reaction

⇒ \(\frac{\text { Molecular weight of } \mathrm{As}_2 \mathrm{~S}_3}{\text { Increase in oxidation number }}=\frac{M}{28}\)

Redox Reactions Chapter 8 Long Answer Solutions Class 11

Question 28. Determine the equivalent mass of Fe₂O₄ in the given Mn = 6-4 = 2 units. reaction: FeO₄ + KMn0_4↓Fe₂O₃ + MnO₂ (Assume that the molecular mass of Fe₃O₄ =M
Answer:

⇒ \(\stackrel{+\mathrm{F} / 3}{\mathrm{Fe}} \mathrm{e}_3 \mathrm{O}_4 \rightarrow \stackrel{+3}{\mathrm{~F}} \mathrm{e}_2 \mathrm{O}_3\stackrel{+\mathrm{F} / 3}{\mathrm{Fe}} \mathrm{e}_3 \mathrm{O}_4 \rightarrow \stackrel{+3}{\mathrm{~F}} \mathrm{e}_2 \mathrm{O}_3\)

In this reaction, the increase in oxidation number for each Pc -atom \(=3-\frac{8}{3}=\frac{1}{3} \text {. }\)

So, the total increase in oxidation number for 3 Fe -atoms

⇒ \(=3 \times \frac{1}{3}=1 \text { unit. }\)

Therefore, the equivalent mass of Fe3O4

⇒ \(=\frac{\text { Molecular mass of } \mathrm{Fe}_3 \mathrm{O}_4}{\text { Increase in oxidation number }}=\frac{M}{1}=M\)

Question 29. What is the ratio of equivalent weights of MnO₄ in acidic, basic & neutral mediums?
Answer:

The reactions that the MnO₄ ion undergoes in acidic, basic, and neutral mediums are as follows. Acidic Medium

⇒ \(\mathrm{MnO}_4^{-}(a q)+8 \mathrm{H}^{+}(a q)+5 e \rightarrow \mathrm{Mn}^{2+}(a q)+4 \mathrm{H}_2 \mathrm{O}(l)\)

• Equivalent weight \(E_1=\frac{M}{5}\) where M = KMn04.
• Basic Medium: MnO₄ (aq) + e→MnO₄ (aq)
• Equivalent weight \(E_2=\frac{M}{1}\)

Neutral Medium:

⇒ \(\mathrm{MnO}_4^{-}(a q)+2 \mathrm{H}_2 \mathrm{O}(l)+3 e \rightarrow \mathrm{MnO}_2(s)+4 \mathrm{OH}^{-}(a q)\)

Therefore \(E_1: E_2: E_2=\frac{1}{5}: 1: \frac{1}{3}=3: 15: 5\)

Question 30. MnO₄ reacts with A^x+ to form AO₃^{– ,}  Mn²⁺, and O2. One mole of MnO₄^– oxidizes 1.25 moles of A^x+ to AO₃^–. What is the value of x?
Answer:

⇒  \(\mathrm{MnO}_4^{-}+\mathrm{A}^{x+} \rightarrow \mathrm{AO}_3^{-}+\mathrm{Mn}^{2+}+\mathrm{O}_2\)

The change in oxidation number of = 5 unit (+7→+2) and that of A = (5- x) unit [+x→+5 in AO_3^-3]

1 mole of MnO₃ reacts completely with 1.25 mole of Ax+

Therefore, 1×5 = 1.25(5 -x)

Solving for x gives x = +1

Thus, the value of x = +1

Question 31. 20 mL solution of 0.1 (M) FeSO₂ as completely oxidized using a suitable oxidizing agent. What is the number of electrons exchanged?
Answer:

20 mL of 0.1(M) FeSO₄

=\(\frac{0.1}{1000} \times 20\)

=\(2 \times 10^{-3} \mathrm{~mol} \text { of } \mathrm{Fe}^{2+}\)

Fe²⁺ is oxidized to Fe³⁺, leaving 1 electron.

Hence, the number of electrons exchanged by 2 x 10-3 mol of Fe²⁺ is

2 × 10^-3× 6.022 × 10²³

= 1.2044  ×  10²¹ electrons

Question 32. What are the oxidation numbers of the underlined elements in each of the following and how do you rationalise your results?

1. Kl₃
2. CH₃COOH

Answer: The chemical structure of KI₃ is K+[1-1→1]¯

In Kl₃-1 ion forms a coordinate Bond with I₂. The Osditaion Number Of Each 1 atom in 12 molecules is zero, and the oxidation number of K+ id +1, therefore from the oxidation number of one I- will be -1

2. The C-1 atom is linked to one O-atom and one OH group, For O -atom and OH -group, the oxidation numbers are 2 and I respectively, As C-1 and C-2 are the atoms of the name element, the covalent linkage between them makes no change In oxidation number of either atom.

So, the oxidation number of C- 1 would be +3 since the total oxidation number of one O-atom and one Oil -group is -3. The total oxidation number of three OH-atoms linked to the C-2 atom Is +3. So, the oxidation number of C-2 would be -3.

Question 33. Justify the following reactions are redox reactions:

1. \(\mathrm{CuO}(s)+\mathrm{H}_2(g) \rightarrow \mathrm{Cu}(s)+\mathrm{H}_2 \mathrm{O}(g)\)

2. \( \mathrm{Fe}_2 \mathrm{O}_3(s)+3 \mathrm{CO}(g) \rightarrow 2 \mathrm{Fe}(s)+3 \mathrm{CO}_2(g)\)

3. \(4 \mathrm{BCl}_3(g)+3 \mathrm{LiAlH}_4(s)\) → \(2 \mathrm{~B}_2 \mathrm{H}_6(g)+3 \mathrm{LiCl}(s)+3 \mathrm{AlCl}_3(s)\)

4. \(2 \mathrm{~K}(s)+\mathrm{P}_2(g) \rightarrow 2 \mathrm{~K}^{+} \mathrm{F}^{-}(s)\)

 5. \( 4 \mathrm{NH}_3(g)+5 \mathrm{O}_2(\mathrm{~g}) \rightarrow 4 \mathrm{NO}(g)+6 \mathrm{H}_2 \mathrm{O}(g)\)

Answer:

1.

In the reaction, the oxidation number of Cu decreases (+2→0) indicating the reduction of CuO, and the oxidation number of 2 increases (0 →+1), indicating the oxidation of H₂. Hence, it is a redox reaction.

2.

In the reaction, the oxidation number of Fe decreases (+3→+0) and that of C increases
→+4). Therefore, the reaction involves the reduction of Fe₂O₃ and the oxidation of CO. Hence, it is a redox reaction.

3.

The reaction involves the reduction of BC1₃ because the oxidation number of B decreases from +3 to -3 and the oxidation of LiAH₄ as the oxidation number increases from -1 to +1. So, it is a redox reaction.

4.

In the reaction, the increase in the oxidation number of K (0→+1) and the decrease in the oxidation number of F (0 to -1) indicate that the former undergoes oxidation and the latter reduces. Hence, the given reaction is a redox reaction.

5.

In the reaction, NH₃ undergoes oxidation because the oxidation number of N-atom increases (-3 to +2), while O₂ undergoes reduction, as is evident from the decrease in the oxidation number of O (0→-2). So, it is a redox reaction.

Redox Reactions Long Question Answers for Class 11 Chemistry

Question 34. Calculate the oxidation number of sulfur, chromium and nitrogen in  \(\mathrm{Cr}_2 \mathrm{O}_7^{2-}\) & NO₃^–. Suggest the structure of these compounds. Count for the
Answer:

⇒ \(\mathrm{Cr}_2 \mathrm{O}_7^{2-}\): If the oxidation number of Cr in \(\mathrm{Cr}_2 \mathrm{O}_7^{2-}\)

Be x, then 2(x)+ 7(-2)

=-2

∴ x = +6

The structure of \(\mathrm{Cr}_2 \mathrm{O}_7^{2-}\) is

Therefore, there is no fallacy.

NO₃^–:

According to a conventional method, the oxidation number of N in

NO₃^–: x+ 3(-2) = -1 or, x = +5

Where x = +3 -1. oxidation number of N in NO₃^–)

However, according to the chemical bonding method, the structure of NO₃^– is

If the oxidation number of N is -0 = 0 the above structure is x,

Then, x+ (-1) + (-2) + (-2)

⇒ \(\begin{gathered}
x+(-1)+(-2)+(-2)=0 \\
\quad\left(\text { for } \mathrm{O}^{-}\right)(\text {for }=0)(\text { for } \rightarrow 0)
\end{gathered}\)

or, x = +5

So, in both conventional and chemical bonding methods. the oxidation number of N in NO-₃ is +5. Therefore, there is no fallacy.

Question 35. Suggest a list of the substances where carbon can exhibit oxidation states from -4 to +4 and nitrogen from -3 to +5
Answer:

Carbon (c):

Nitrogen (N):

Question 36. While sulfur dioxide and hydrogen peroxide can act as oxidizing as well as reducing agents in their reactions, ozone and nitric acid act only as oxidants. why?
Answer:

A species can act as both oxidant and reductant am one of its constituent atoms has an intermediate value of oxidation number. So, in a reaction the atom can increase or decrease its oxidation number i.e., it can act as an oxidant as well as a; reductant.

1. In SO₂, the oxidation number of S is +4. The highest and lowest oxidation numbers of S are +6 and -2 respectively. Therefore, the S-atom in SO₂ can increase its oxidation number in a reaction in which SO₂ acts as a reductant and decrease its oxidation number in a reaction in which SO₂ plays the role of an oxidant. Hence, SO₂ can act as an oxidant as well as a reductant.

2. In H₂O₂, the oxidation number of O is  -1 The highest and lowest oxidation numbers of oxygen are -2 and O respectively. Therefore, the oxygen atom in H₂O₂ is capable of increasing or decreasing its oxidation number. In the reaction in which H₂O₂ acts as an oxidant, the oxidation number of oxygen decreases from -1 to -2 and in the reaction in which it acts as a reductant, the oxidation number of oxygen increases from -1 to 0. Hence, H₂O₂ can act both as an oxidant and a reductant.

3. In O₃, the oxidation number of oxygen is zero. Oxygen can show two oxidation numbers, -1 and -2. So, the oxidation number of oxygen O₃ can reduce to -1 or -2, but it can never increase. Hence, O₃ can act only as an oxidant.

4. In HNO₃, the oxidation number of nitrogen is +5. It is the maximum oxidation number that nitrogen can exhibit. So, the only opportunity for nitrogen in HNO₃ is to decrease its oxidation number. Hence, HNO₃ can act only as an oxidant.

Question 37. Consider the reactions:

1. 6CO₂(g) + 6H₂O(l)→ C₆H₁₂O₆(aq) + 6O₂(g)

2. O₃(g) + H₂O₂(l) → H₂O(Z) + 2O₂(g)

Why it is more appropriate to write these reactions

1. 6CO₂(g) + 12H₂O(l) → C₆H₁₂O₆(aq) + 6H₂O(l) +6O₂(g)

2. O₃(g) + H₂O₂(l) → H₂O(l) +O₂(g) + O₂(g)

Also, suggest a technique to investigate the path of the above (1) and (2) redox reactions

Answer:

The reaction shown by the equation 1 takes place in the photosynthesis process. From the equation 1, it may seem that the reaction involves only the consumption of H₂O. However, if we look at the steps that are supposed to be involved in the photosynthesis reaction, it becomes evident that consumption as well as formation of H₂O takes place in the photosynthesis reaction. The proposed steps of the photosynthesis reaction are

1. Decomposition of H₂O into H₂ and O₂

12H₂O(Z)→12H₂(g) + 6O₂(g) …………………………(1)

2. Formation of C₆H₁₂0O₆ and H₂O due to reduction of CO₂(g) by H₂(g) produced in step.

6CO₂(g) + 12H₂(g)→C₆HI₂O₆(s) + 6H₂O(l)…………………………(2)

Combining equations (1) and (2) gives the complete reaction for the photosynthesis process.

6CO₂(g) + 12H₂O(l) → C₆H₁₂O₆(s) + 6O₂(g) +6H₂O(l)…………………………(3)

Thus, equation (3) will be more appropriate for representing the photosynthesis reaction because it gives the actual stoichiometry of the reactants and the products involved in the given reaction.

From the equation 2, the source of O₂ formed in the reaction is not obvious. One may think O₂ is formed from O₃ or H₂O₂ or both O₃ and H₂O₂. The detailed steps of this reaction as shown below reveal that O₂ is formed from both O₃ and H₂O₂.

……………..(1)

Therefore, it is appropriate to represent the reaction by equation (1).

To investigate the paths of the reaction 1 and 2, we adopt the tracer technique method. In this method, we use H₂O¹⁸ instead of H₂O for reaction 1 and H₂O₂¹⁸ instead of H₂O₂ for reaction 2.

Question 38. Whenever a reaction between an oxidizing agent and a reducing agent is carried out, a compound of a lower oxidation state is formed if the reducing agent is in excess, and a compound of a higher oxidation state is formed if the oxidizing agent is in excess. Justify this statement by giving three illustrations.
Answer:

1. The given statement can be justified from the examples of j reactions mentioned below.

The reaction of C (reductant) with O₂ (oxidant) may result in CO or CO₂ or a mixture of CO and CO₂. However, if this reaction is initiated with the excess amount of C, the only product that forms is CO. On the other hand, if O₂ is taken in excess in the reaction, only CO₂ is formed. In CO, the oxidation state of C is +2, and in CO₂, it is +4.

Thus, we see that taking an excess amount of reductant leads to the formation of a compound lower oxidation state. Conversely, a compound of a higher oxidation state is formed when the oxidant is taken in excess.

The reaction of P₄ (reductant) with Cl₂ (oxidant) results in PCl₃ when P₄ is taken in excess, while it results in PCl₅ when Cl₂ is taken in excess.

The oxidation state of PCl₃ is +3 and that in PC1₅ is +5. Thus, an excess amount of reductant produces an oil compound lower oxidation state and an excess amount of oxidant produces a compound with a higher oxidation state.

The same thing happens when Na (reductant) is reacted with O₂ (oxidant).In the presence of excess Na, the resulting compound is Na₂O, in which the oxidation state of oxygen is -2 in the presence of excess O₂, the resulting compound is Na202, in which the oxidation state of oxygen is -1. → ↑

[In this reaction, the mass of Na is 46g and that of oxygen is 64 g]

NCERT Class 11 Chemistry Redox Reactions Long Answer Solutions

Question 39. How do you count for the following observations? Although alkaline potassium permanganate and acidic potassium permanganate both are used as oxidants, yet In the manufacture of benzoic acid from toluene we use alcoholic potassium permanganate as an oxidant. Why? Write a balanced redox equation for the reaction.

When concentrated sulphuric acid is added to an inorganic mixture containing chloride, we get colorless pungent-smelling gas HC1, but if the mixture contains bromide then we get red vapour of bromine. Why?
Answer:

The reaction in acid medium:

Multiplying equation (1) by 6 and equation (2) by 5 and then adding them together, we have

The reaction in alkaline or neutral medium:

Multiply equation (3) by 2 and then adding it to equation (4), we have

Even though toluene oxidizes to benzoic acid in the presence of acidic or alkaline KMnO₄, the manufacture of benzoic acid from toluene is usually carried out by using alcoholic KMnO₄ as an oxidant.

This is because ofthe following advantages:

The use of alcoholic KMnO₄ is cost-effective because carrying out the reaction in the presence of it does not require adding either acid or alkali in the reaction medium. In a neutral medium, OH- ions are produced during the reaction.

Both KMnO₄ and toluene are soluble in alcohol and they form a homogeneous mixture. This facilitates the reaction and contributes towards speeding up the reaction.

When concentrated H₂SO₄ is added to an inorganic mixture containing chloride, HC₁, which has a pungent smell, is produced.

Question 40. Identify the substance oxidized, reduced, oxidizing agent, and reducing agent for each of the following reactions

1. \(2 \mathrm{AgBr}(s)+\mathrm{C}_6 \mathrm{H}_6 \mathrm{O}_2(a q) \rightarrow 2 \mathrm{Ag}(s)+2 \mathrm{HBr}(a q)+\mathrm{C}_6 \mathrm{H}_4 \mathrm{O}_2(a q)\)

2. \(\mathrm{HCHO}(l)+2\left[\mathrm{Ag}\left(\mathrm{NH}_3\right)_2\right]^{+}(a q)+3 \mathrm{OH}^{-}(a q)\)

→ \(2 \mathrm{Ag}(s)+\mathrm{HCOO}^{-}(a q)+4 \mathrm{NH}_3(a q)+2 \mathrm{H}_2 \mathrm{O}(l)\)

3. \(\mathrm{HCHO}(l)+2 \mathrm{Cu}^{2+}(a q)+5 \mathrm{OH}^{-}(a q) \rightarrow \mathrm{Cu}_2 \mathrm{O}(s)+\mathrm{HCOO}^{-}(a q)+3 \mathrm{H}_2 \mathrm{O}(l)\)

4. \(\mathrm{N}_2 \mathrm{H}_4(l)+2 \mathrm{H}_2 \mathrm{O}_2(l) \rightarrow \mathrm{N}_2(g)+4 \mathrm{H}_2 \mathrm{O}(l)\)

5.\(\mathrm{Pb}(s)+\mathrm{PbO}_2(s)+2 \mathrm{H}_2 \mathrm{SO}_4(a q) \rightarrow 2 \mathrm{PbSO}_4(s)+2 \mathrm{H}_2 \mathrm{O}(l)\)

Answer:

Question 41. Consider the reaction:

1. 2S₂O₃(aq) + I₂(s) →S₄O₆^2-aq) + 2I^–(aq)

2. S₄O₃^2-(aq) + 2Br₂(Z) + 5H₂O(l) →  2SO₄^2-(aq) + 4Br^–(aq)+10H⁺(aq)

Answer:

The standard reduction potential for Br₂/2Br^– system is greater than that for I2/2I- system

⇒ \(E_{\mathrm{Br}_2 / 2 \mathrm{Br}}^0=1.09 \mathrm{~V}\)

And \(E_{1_2 / 21^{-}}^0=0.54 \mathrm{~V}\)

This indicates that Br₂ is a stronger oxidizing agent than I. The average oxidation number of S in

⇒ \(\mathrm{S}_2 \mathrm{O}_3^{2-}\) is +2. and that in \(\mathrm{S}_4 \mathrm{O}_6^{2-}\) is 2.5, while the oxidation number of S in SO₂– is +6.

The oxidation number per S-atom changes by 0.5 units in the reaction

⇒  \(\mathrm{S}_2 \mathrm{O}_3^{2-} \rightarrow \mathrm{S}_4 \mathrm{O}_6^{2-}\) while in the reaction \(\mathrm{S}_2 \mathrm{O}_3^{2-} \rightarrow \mathrm{SO}_4^{2-}\) This change occurs by 4 units.

Being a stronger oxidizing agent, Br₂ is capable of increasing the oxidation number of S in

⇒ \(\mathrm{S}_2 \mathrm{O}_3^{2-}\) To the maximum oxidation number of 6, thereby leading to the formation of S₂O₃^2-ion.

On the other hand, I₂, being a weaker oxidizing agent, increases the oxidation number of Sin S₂O₃^2- to an oxidation number of 2.5 and results in the formation of

⇒ \(\mathrm{S}_4 \mathrm{O}_6^{2-}\) ion.

Question 42. Justify giving reactions that among halogens, fluorine is the best oxidant, and among hydrohalic compounds, hydroiodic acid is the best reductant
Answer:

The standard redox potentials (or standard reduction potentials) ofthe redox couples formed by halogens are

Are doxcouple consists of a reduced form and an oxidised form. The larger the value of E° for a redox couple, the greater the tendency of its oxidized form to get reduced and the smaller the tendency of its reduced form to oxidize. The reverse is true when the value of E° for a redox couple is small.

Combining this idea with standard electrode potentials of the redox couples given, we can infer that the tendency of oxidized forms (i.e., F₂, Cl₂, Br_2, and I₂) to get reduced or the strength of oxidizing power of the oxidized forms follows the order: F₂ > Cl₂ > Br₂ > I₂, and the tendency of reduced forms {i.e., F-, Cl-, Br- and I-) to get oxidized or the strength of reducing power ofthe reduced forms follows the order:

I¯> Br¯> Cl¯ > F¯

As the oxidizing power of F₂ is the highest among the halogens, it is capable of oxidizing other halides to the corresponding halogens. No other halogen except F₂, has this ability

⇒ \(\mathrm{F}_2(g)+2 \mathrm{Cl}^{-}(a q) \rightarrow 2 \mathrm{~F}^{-}(a q)+\mathrm{Cl}_2(g)\)

⇒ \(\mathrm{F}_2(g)+2 \mathrm{Br}^{-}(a q) \rightarrow 2 \mathrm{~F}^{-}(a q)+\mathrm{Br}_2(l)\)

⇒ \(\mathrm{F}_2(g)+2 \mathrm{I}^{-}(a q) \rightarrow 2 \mathrm{~F}^{-}(a q)+\mathrm{I}_2(s)\)

⇒ \(\mathrm{Cl}_2(g)+2 \mathrm{Br}^{-}(a q) \rightarrow 2 \mathrm{Cl}^{-}(a q)+\mathrm{Br}_2(l)\)

⇒ \(\mathrm{Cl}_2(g)+2 \mathrm{I}^{-}(a q) \rightarrow 2 \mathrm{Cl}^{-}(a q)+\mathrm{I}_2(s)\)

⇒ \(\mathrm{Br}_2(l)+2 \mathrm{I}^{-}(a q) \rightarrow 2 \mathrm{Br}^{-}(a q)+\mathrm{I}_2(s)\)

Therefore, F₂ has the strongest oxidizing power among the halogens. The oxidation of a hydrohalic acid produces its halogen. The tendency of a hydrohalic acid to get oxidized or the reducing power of a hydrohalic acid is high when the halide ion of the hydrohalic acid exhibits a greater tendency to get oxidized. As the tendency ofhalide ions to get oxidized follows the order I¯ > Br¯ > Cl¯ > F-, the reducing power of hydrohalic acids will follow the order HI>HBr>HCl>HF.

The following reactions confirm this:

HI or HBr can reduce H₂SO₂ to SO₂, but HC1 or HF cannot reduce it.

⇒ \(2 \mathrm{HI}+\mathrm{H}_2 \mathrm{SO}_4 \rightarrow \mathrm{I}_2+\mathrm{SO}_2+2 \mathrm{H}_2 \mathrm{O}\)

⇒ \(2 \mathrm{HBr}+\mathrm{H}_2 \mathrm{SO}_4 \rightarrow \mathrm{Br}_2+\mathrm{SO}_2+2 \mathrm{H}_2 \mathrm{O}\)

I^– can reduce Cu²⁺ to Cu⁺, but Br^– cannot.

⇒ \(2 \mathrm{Cu}^{2+}(a q)+4 \mathrm{I}^{-}(a q) \rightarrow \mathrm{Cu}_2 \mathrm{I}_2(s)+\mathrm{I}_2(s)\)

⇒ \(\mathrm{Cu}^{2+}(a q)+2 \mathrm{Br}^{-}(a q) \rightarrow \text { No reaction }\)

Therefore, we can conclude that HI is the strongest reducing agent among the hydrohalic acids.

Question 43. Why does the following reaction occur? XeO₆^-4 (aq) + 2F^–(aq) + 6H⁺(aq) →  XeO₃(g) + F₂(g) + 3H₂O(l), What conclusion about the compound Na₄XeO₆ (of which XeO₃ is a part) can be drawn from the reaction?
Answer:

The oxidation numbers of Xe in XeO₆^-4 and XeO₃ are +8 and +6 respectively. Thus, in the reaction the oxidation number of Xe decreases, and hence XeO₆^-4– undergoes reduction and acts as an oxidising agent. On the other hand, the oxidation number of F increases from -1 to 0.

Therefore, in the reaction fluorine undergoes oxidation and hence it acts as a reductant. As the reaction is spontaneous and XeO₆^-4  oxidizes F^–, it can be concluded that Na₄XeO₆ has stronger oxidizing power than F₂.

Class 11 Chemistry Chapter 8 Long Questions Redox Reactions

Question 44. Consider the reactions:

1. H₃PO₂(aq) + 4AgNO(aq) + 2H₂O(l) → H₃PO₂(aq) + 4Ag(s) + 4HNO₃(aq)

2. H₃PO₂(aq) + 2CuSO₄(aq) + 2H₂O(Z)→ H₃PO₄(aq) + 2Cu(s) + H₂SO₄(aq)

3.  C₆H₅CHO(l) + 2[Ag(NH₃)₂]⁺(aq) + 3OH^–(aq) → C₆H₅COO^–(aq) + 2Ag(s) + 4NH₃(aq) + 2H₂O(l)

4. C₆H₅CHO(l) + 2Cu²⁺(aq) + 5OH^– →(aq) No change observed

What inference do you draw about the behavior of Ag⁺ and Cu²⁺ from these reactions?
Answer:

1. The reaction involves the reduction of the Ag⁺ ion to Ag and the oxidation of H₃PO₂ to H₃PO₄. Thus, in this reaction, the Ag+ ion behaves as an oxidant. It oxidizes H₃PO₂ to H₃PO₄.

2. The reaction involves the reduction of Cu²⁺ ion to Cu and the oxidation of H₃PO₂ to H₃PO₄. Thus, in this reaction, the Cu²⁺ ion behaves as an oxidant. It oxidizes H₃PO₂ to H3PO₄.

3.The reaction involves the oxidation of C₆H₅CHO to C₆H₅COOH and the reduction of [Ag(NH₃)₂]⁺ to Ag. Thus, in this reaction, the Ag⁺ ion acts as an oxidant. It oxidizes C₆H₅CHO to C₆H₅COOH.

This reaction indicates that the Cu²⁺ ion is not capable of oxidizing C₆H₅CHO. This explains why the Cu²⁺ ion is a weaker oxidizing agent than the Ag⁺ ion.

Question 45. What sorts of information can you draw from the following reaction?
Answer:

Let us first analyze whether (CN)₂ in the reaction gets oxidized or reduced or simultaneously oxidized as well as reduced. To know this the knowledge of the oxidation states of C in (CN)₂, CN, and CNO- are required.

The oxidation state of C in (CN)₂ is

⇒ \(+3\left[(\stackrel{+3-3}{(\mathrm{CN}})_2\right]\) is +2 \(\mathrm{CN}^{-}\left[\mathrm{CN}^{-}\right] \text {and }+4 \text { in } \mathrm{CNO}^{-}\left[\mathrm{C}^{+3-32} \mathrm{CN}^{-}\right]\)

Now let us consider the given equation

⇒  \((\stackrel{+3}{\mathrm{C}} \mathrm{N})_2(g)+2 \mathrm{OH}^{-}(a q) \xrightarrow[+2]{\mathrm{C}} \mathrm{N}^{-}(a q)+\stackrel{+4}{\mathrm{C}} \mathrm{NO}^{-}(a q)+\mathrm{H}_2 \mathrm{O}(l)\)

From this equation, we see that (CN)₂ reduced to the oxidation number of C reduces (+3→+2) in this change, and It gets oxidized to CNO^– because the oxidation number of C Increases (+3→+4) In this change. Thus, from this reaction, we have the following information: CD In an alkaline medium cyanogen gas dissociates into cyanide Ion (ON-) and cyanate Ion (CNO^–).

It Is a redox reaction. More particularly, it is a disproportionation reaction because (CN)₂ undergoes oxidation and reduction simultaneously. Cyanogen is a pseudohalogen. It acts as a halogen on reacting with alkalis.

Question 46. The Mn³⁺ ion Is unstable In solution and undergoes disproportionation to give Mn²⁺, MnO₂, and H⁺ ions. Write a balanced ionic equation for the reaction.
Answer:

Mn³⁺ is unstable in an aqueous medium and undergoes a disproportionation reaction, forming Mn³⁺, MnO₂ and H⁺. So, the reaction is—

Here the oxidation reaction is

⇒ \(\mathrm{Mn}^{3+}(a q)+2 \mathrm{H}_2 \mathrm{O}(l) \rightarrow \mathrm{MnO}_2(s)+4 \mathrm{H}^{+}(a q)+e \quad \cdots[1]\)

Adding equation (1) and equation (2), we have

⇒ \(2 \mathrm{Mn}^{3+}(a q)+2 \mathrm{H}_2 \mathrm{O}(l) \rightarrow \mathrm{MnO}_2(s)+\mathrm{Mn}^{2+}(a q)+4 \mathrm{H}^{+}(a q)\)

This is the balanced equation for the disproportionation reaction that the Mn³⁺ ion undergoes in an aqueous medium.

Question 47. Consider the elements: Cs, Ne, I, and F

1. Identify the element that exhibits only a negative oxidation state.
2. Identify the element that exhibits only a positive oxidation state.
3. Identify the element that exhibits both positive and negative oxidation states.
4. Identify the element that exhibits neither the negative nor the positive oxidation state

Answer:

1. Being an element of the highest electronegativity, F always shows a negative oxidation state. It exhibits only a -1 oxidation state

2. Cs is an alkali metal and shows a strong electropositive character. As a result, it always shows a positive oxidation state. It exhibits only a +1 oxidation state.

3. Like other halogens, I also show a -1 oxidation state. In addition, it shows positive oxidation states, +1, +3, +5, and +7 when it forms compounds with more electronegative elements.

4. Ne is an inert element and does not tend to gain or lose electrons. As a result, it shows neither a positive oxidation state nor a negative oxidation state.

Question 48. Chlorine is used to purify drinking water. Excess of chlorine is harmful. The excess chlorine is removed by treating it with sulfur dioxide. Present a balanced equation for this redox change taking place in water.
Answer:

The reaction that occurs when SO₂ is used to remove excess Cl₂ in drinking water is

⇒ \(\mathrm{Cl}_2(a q)+\mathrm{SO}_2(a q) \rightarrow 2 \mathrm{Cl}^{-}(a q)+\mathrm{SO}_4^{2-}(a q)\)

Oxidation reaction: \(\stackrel{+4}{\mathrm{SO}_2}(a q) \xrightarrow{+6} \mathrm{SO}_4^{2-}(a q)\)

To balance O-atoms, we add 2H₂O to the left-hand side and 4H+ to the right-hand side.

⇒ \(\mathrm{SO}_2(a q)+2 \mathrm{H}_2 \mathrm{O}(l) \rightarrow \mathrm{SO}_4^{2-}(a q)+4 \mathrm{H}^{+}(a q)\) ……………….(1)

Balancing charges on both sides, we have

Reduction reaction: Cl₂(aq) + 2e→2Cl^–(aq)………………..(2)

Adding equation (1) to equation (2), we have

⇒ \(\mathrm{Cl}_2(a q)+\mathrm{SO}_2(a q)+ 2 \mathrm{H}_2 \mathrm{O}(l)\) → \(\mathrm{SO}_4^{2-}(a q)+2 \mathrm{Cl}^{-}(a q)+4 \mathrm{H}^{+}(a q)\)

This is the balanced equation for the reaction.

Question 49. Refer to the periodic table given in your book and now answer the following questions:

1. Select the possible non-metals that can show a disproportionation reaction.
2. Select three metals that can show a disproportionation reaction.

Answer:

1. Non-metals such as P4(s), Cl₂(g), and Br₂(Z) undergo disproportionation reaction.

⇒ \(\mathrm{P}_4(s)+3 \mathrm{NaOH}(a q)+3 \mathrm{H}_2 \mathrm{O}(l)\) → \(\mathrm{PH}_3(g)+3 \mathrm{NaH}_2 \mathrm{PO}_2(a q)\)

⇒ \(\mathrm{Cl}_2(g)+6 \mathrm{NaOH}(a q)(\mathrm{Hot})\) → \(5 \mathrm{NaCl}(a q)+\mathrm{NaClO}_3(a q)+3 \mathrm{H}_2 \mathrm{O}(l)
\)

⇒ \(\mathrm{Br}_2(l)+6 \mathrm{NaOH}(a q)(\mathrm{Hot})\)→ \(5 \mathrm{NaBr}(a q)+\mathrm{NaBrO}_3(a q)+3 \mathrm{H}_2 \mathrm{O}(l)\)

Three metals that can show disproportionation reactions are copper, gallium and manganese.

⇒ \(2 \stackrel{+1}{\mathrm{C}} u^{+}(a q)\rightarrow \stackrel{0}{\mathrm{Cu}}(s)+\stackrel{+2}{\mathrm{Cu}^{2+}}(a q)\)

⇒  \(3 \mathrm{Ha}^{+}(a q)\rightarrow \stackrel{+3}{\mathrm{Ga}}^{3+}(a q)+2 \stackrel{\ominus}{\mathrm{Ga}}(s)\)

⇒ \(2 \mathrm{Mn}^{3+}(a q)+2 \mathrm{H}_2 \mathrm{O}(l)\) → \(\mathrm{MnO}_2(s)+\mathrm{Mn}^{2+}(a q)+4 \mathrm{H}^{+}(a q)\)

Redox Reactions Chapter 8 NCERT Long Answer Questions Class 11

Question 50. In Ostwald’s process for the manufacture of nitric acid, the first step involves the oxidation of ammonia gas by oxygen gas to give nitric oxide gas and steam. What is the maximum weight of nitric oxide that can be obtained starting only with 10.00 g of ammonia and 20.00 g of oxygen?
Answer:

Reaction:

4NH₃(g) + 5O₂(g) → 4NO(g) + 6H₂O(g)

4 × 17 g = 68 g 5 × 32 g

= 160 g 4 × 30 g = 120 g

Therefore, 160 g O₂ is required to oxidize 68 g NH₃.

Therefore, 160 g O₂ is required to oxidize 68 g NH₃.

20g O₂ is required to oxidise \(\frac{68}{160} \times 20 \mathrm{~g}\)

= 8.5 g of NH₃

So, here O₂ is the limiting reagent. The amount of nitric oxide produced depends upon the amount of oxygen taken and not on the amount of NH3 taken

According to the above equation,

160 g O₂ produces 120 g NO

⇒ \(20 \mathrm{~g} \mathrm{O}_2 \text { produces } \frac{120}{160} \times 20 \mathrm{~g} \mathrm{NO}=15 \mathrm{~g} \mathrm{NO}\)

Thus the reaction between 10 g NH₃ and 20gO₂ produces a maximum amount of 15 g NO.

NCERT Solutions For Class 11 Chemistry Chapter 5 States Of Matter Gases And Liquids Very Short Question And Answers

Question 1 Arrange O₂, CO₂, Ar, and SO₂ gases to present a sample of air in order of their increasing pressures.
Answer:

⇒ \(d_1=\frac{P M}{R T}, d_2=\frac{P M}{4 \times 8 R T}=\frac{1}{32} \frac{P M}{R T}=\frac{d_1}{32}\)

Question 2. Why is it not possible to liquefy an ideal gas?
Answer: Because of the absence of intermolecular forces of attraction in an ideal gas, such a gas cannot be liquefied

Question 3. Why is the nib of the fountain pen split?
Answer: The split part of the nib of a fountain pen acts like a capillary tube. The ink moves towards the tip of the die nib by capillary action against gravitation through the split par.

Read and Learn More NCERT Class 11 Chemistry Very Short Answer Questions

Question 4. At a constant temperature, gas A (volume VA and pressure PA) is mixed with gas B (volume VR and pressure PB). What will the total pressure ofthe gas mixture be?
Answer:

Total pressure ofthe gas mixture \(P=\frac{P_A V_A+P_B V_B}{V_A+V_B}\)

States of Matter Chapter 5 Class 11 Very Short Questions

Question 5. For which of the following gas mixtures is Dalton’s law of partial pressures applicable? NO + O₂, CO₂ + CO , CO + O_2, CH₄ + C₂H₆,CO + H₂
Answer: Dalton’s law is applicable in case NO reacts with O₂ to form NO₂. CO reacts with O₂ to form CO₂. Hence, Dalton’s law does not apply to 1 and 3.

Question 6. In a mixture of A, B, and C gases, the mole fractions of A are 0.25 and 0.45, respectively. If the total pressure of the mixture is P, then find the partial pressure of B in the mixture.
Answer:

In the gas mixture, the mole of B =1- (0.25 + 0.45) = 0.3.

∴ The partial pressure of B in the mixture = 0.3 p.

Question 7. Why are diffusion rates of N₂O and CO₂ gases the same under identt of conditions?
Answer: N₂O and CO₂ have the same molar mass. So, diffusion rates will be equal at a certain temperature and pressure.

Question 8. At constant temperature and pressure, the rate of diffusion of H₂ gas is A/15 times. Find the value of n.
Answer:

⇒ \(\frac{r_{\mathrm{H}_2}}{r_{\mathrm{C}_n \mathrm{H}_{4 n-2}}}=\sqrt{\frac{16 n-2}{2}}=\sqrt{8 n-1}=\sqrt{15}\)

Question 9. Besides the lower layer, CO₂ is also found in the upper layer of the atmosphere, although it is heavier than O₂ or N₂—Explain.
Answer: The rate of diffusion of a gas is not influenced by the gravitational force. Hence, CO₂ diffuses throughout the atmosphere instead of residing only at the lower layer of the atmosphere.

Question 10. The molecular masses of A, B, and C are 2, 4, and 28, respectively. Arrange them according to their increasing rates of diffusion.
Answer:

Molar masses of the three gases follow the order: MA < MB < Mc So, at a certain temperature and pressure, diffusion rates will be in the order: rC<rB<rA.

NCERT Solutions Class 11 Chemistry Chapter 5 Very Short Q&A

QuestionWhichwhich type of gas molecules are the energy and translational kinetic energy equal?
Answer: For monatomic gases (He, Ne, etc.) the total kinetic energy and translational kinetic energy are equal.

Question 12. Which type of velocity does a gas molecule with average kinetic energy possess?
Answer: The average kinetic energy of a gas molecule \(=\frac{1}{2} m c_{r m s}^2.\). So, a gas molecule with average kinetic energy has the root-mean-square velocity.

Question 13. On what factors does the total kinetic energy of the molecules in a gas depend?
Answer: The total kinetic energy of the molecules in a gas depends on the absolute temperature as well as the amount of the gas.

Question 14. Between H₂ and CO₂ gas, which one has the value of compressibility factor greater than 1 at ordinary temperature and pressure?
Answer: At ordinary temperature and pressure, the compressibility factor of H₂ is greater than 1.

Question 15. Which types of intermodular forces of attraction act between the modules in liquid HF?
Answer: HF is a polar covalent molecule. Hence, the forces of attraction between HF molecules in their liquid state are dipole-dipole attraction and H -H-H-bonding.

Question 16. What do you mean by the pressure of the gas?
Answer: Since E₂>E₁, T₂>T₁. This is because, with the increase in the absolute temperature of a gas, the average kinetic energy of the gas molecules increases

Very Short Questions and Answers for Class 11 Chemistry Chapter 5

Question 17. Mention the variables and constant quantities in Charles’ law
Answer: Variables; Volume ( V) and absolute temperature (T) and Constants: Mass (m) and pressure (P) of the gas.

Question 18. What is the numerical value of N/n?[N and n are the number of gas molecules and number of moles of gas]
Answer: Number of gas molecules (N) = several moles of the gas (n) x Avogadro’s number or\(\frac{N}{n}\) = Avogadro’s number = 6.022 x1023.

Question 19. The equation of state of a real gas is P(V-b) = RT. Can this gas be liquefied?
Answer: For the given gas, the value of van der Waals constant a = 0, indicates the absence of intermolecular forces of attraction in the gas. So this gas cannot be liquefied.

Question 20. At 25°C, the vapour pressure of ethanol is 63 torrs. What does it mean?
Answer: At 25°C, the pressure exerted by eth vapour vapour in equilibrium with the liquid ethanol is 63 torrs.

Question 21. Why is the equilibrium established in the evaporation of a liquid in a closed vessel at a constant temperature called dynamic equilibrium?
Answer: This is so called because the process of evaporation and condensation does not stop at equilibrium and they keep on occurring equally and take

Question 22. Which one between water and ethanol has greater surface tension at a particular temperature?
Answer: As intermolecular forces of attraction are stronger in water than in ethanol, the surface tension of water is greater than that of ethanol.

Question 23. Plot density vs pressure for a fixed mass of an ideal gas at a constant temperature.
Answer: Since docs for a given mass of gas at a constant temperature.

Chapter 5 States of Matter Very Short Answer Solutions

Question 24. What are the molar volumes of nitrogen and argon gases at 273.15K temperature and 1 atm pressure? [consider both the gases behave ideally]
Answer: At 273.15K and late pressure, both nitrogen and argon behave ideally. Hence, at this temperature and pressure, the molar volume of each of them will be 22.4L

Question 25. What is the value of the surface tension of a liquid at its critical temperature?
Answer: The surface tension of a liquid at critical temperature is zero because the surface of separation between the liquid and vapour disappears at this temperature.

Question 26. Among the following properties of a liquid, which one increases with the increase in temperature? Surface tension, viscosity and vapour pressure
Answer: Vapour pressure increases with an increase in temperature

Question 27. At a given temperature, the viscosity of liquid A is greater than that of liquid B. Which of these two liquids has stronger intermolecular forces of attraction?
Answer: The stronger the intermolecular forces of attraction of a liquid, the higher the viscosity will be. Therefore, the inter¬ molecular forces of attraction of A will be greater than B

Question 28. How does the average velocity or the root mean square velocity of gas molecules depend on temperature and pressure?
Answer: The average kinetic energy (c) and the root mean square velocity (c₂) of gas molecules are given by \(\bar{c}=\sqrt{\frac{8 R T}{M}}\) and \(c_{r m s}=\sqrt{\frac{3 R T}{M}}\)

NCERT Class 11 Chemistry Chapter 5 Gases and Liquids Short Q&A

Question 29. Why does oil spread over water when it is poured over water
Answer: The surface tension of water is greater than that of oil. Also, the density of oil is less than that of water. When oil is poured over water, the higher surface tension of water causes oil to spread over water.

Question 30. The vapour pressures of benzene and water at 50°C are 271 and 92.5 torr, respectively. Which one would you expect to have stronger intermolecular forces of attraction?
Answer: A liquid with strong intermolecular forces of attraction has low vapour pressure. Thus, intermolecular forces of attraction are stronger in water.

Question 31. Give two examples where capillary action occurs.
Answer: Due to capillary action, water from the soil reaches the leaves of a tree through its sWaterwater comes out through the pores of a clay pot and evaporates. As a result, the water in the pot gets cooled.

Question 32. Comment on the validity of Boyle’s law for the following reaction: N₃O₄(g) 2NO₂(g)
Answer: The number of molecules of N₂O₄ and NO₂ varies with the pressure at constant temperature. Hence, the mass ofthe gas mixture does not remain constant. Thus, Boyle’s law is not applicable here.

Question 33. The normal boiling point of diethyl ether is 34.6°C What will be its vapour pressure at this temperature?
Answer: At the normal boiling point of a liquid, the vapour pressure of the liquid is equal to the atmospheric pressure. Therefore, the vapour pressure of diethyl ether is at 34. Temperatureature is 1 atm or 760 torr.

Question 34. The normal boiling points of ethanol and benzene are 78.3°C and 80°C, respectively. Is the vapour pressure of ethanol lower than, greater than or equal to the vapour pressure of benzene?
Answer:

At the normal boiling point of a liquid, the vapour pressure of the liquid is equal to the atmospheric pressure. Therefore, the vapour pressure of ethanol at 78.3°C and that of benzene at 80°C are the same and equal to 1 atm.

Question 35. The normal boiling points of two gases A and B are -150°C and -18°C, respectively. Which one of the two gases will behave more like an ideal gas at STP?
Answer: The very low boiling point of A implies the very weak intermolecular forces of attraction in gas A. Hence, gas A will show more ideal behaviour at STP.

Very Short Answer Solutions for States of Matter Class 11

NCERT Solutions For Class 11 Chemistry Chapter 5 States Of Matter Gases And Liquids Fill In The Blanks

Question 1. 0.1 atm = _________________  Pa =___________________
Answer:

1. 1.013 × 10⁴

2. 76

Question 2. The plot of pressure (P) versus temperature (T) for an  ideal gas will be a straight line passing through the origin _____________  and ______________________ remain constant
Answer: Mass and volume

Question 3. At a given temperature and pressure, the density of CO₂ gas is greater than N2 gas, because  it the ___________________ greater than CO₂
Answer:  Molecular mass

Question 4. The density of CO₂ at ___________________  standard atmospheric pressure is 1.788 g-L^-1
Answer: 27°C

Gases and Liquids Chapter 5 Class 11 Very Short Answer Questions

Question 5. The velocity of the gas molecules having average kinetic  energy is called  ___________________ 
Answer: Root mean square velocity

Question 6. At a particular temperature, the average kinetic energies of the S02 molecule and H2 molecule are___________________ 
Answer: Equal

Question 7. The most probable velocity of He atoms at 127°C is_____________
Answer: 40.78 m.s^-1

Question 8. The volume of 1 mole of a gas at STP is smaller than 22.4 L. The compressibility factor of that gas at STP is
___________________  one.
Answer: Less than

Question 9. In van der Waals equation__ _________________ effective size ofthe gas molecules.
Answer: ‘b’

NCERT Class 11 Chemistry Chapter 5 States of Matter Short Q&A

Question 10. At low pressure and a particular temperature, the pressure of 1 mol of an ideal gas is ___________________  a real gas.
Answer: Greater than

Question 11. Due to the ___________________  becomes spherical.
Answer: Surface tension

Question 12. The aqueous solution of soaps can spread like a thin film because ___________________  the surface water tension of the aqueous solution of soap is
Answer: Less

Question 13. At a particular temperature, the viscosity coefficient of ethyl alcohol is  ___________________ than dimethyl ether
Answer: Greater.

NCERT Class 11 Chemistry Equilibrium Long Question And Answers

Question 1. Equilibria involving physical and chemical changes are dynamic in nature—why?
Answer:

In a system, if two processes occur simultaneously at the same rate, then the system is said to be in a state of dynamic equilibrium. When a chemical reaction remains at equilibrium, the forward and the backward reactions occur simultaneously at the same rate.

Due to this, the equilibrium established in a chemical reaction is regarded as a dynamic equilibrium.

Similarly, when a physical process remains at equilibrium, the two opposite processes occur simultaneously at the same rate.

Read and learn More NCERT Class 11 Chemistry

For this reason, a physical equilibrium is also dynamic. For example, at equilibrium established during the evaporation of a liquid in a closed container, the evaporation of the liquid and the condensation of its vapor take place simultaneously at the same rate.

Long Answer Questions for Class 11 Chemistry Equilibrium

Question 2. The equilibrium established in the dissolution of a solid in a liquid or a gas in a liquid is dynamic. Explain
Answer:

If a solid solute is continuously dissolved in a suitable solvent, eventually a saturated solution of the solute is obtained. In this solution, an equilibrium exists between dissolved solute and undissolved solute.

At this equilibrium, the solute particles from undissolved solid solute get dissolved at the same rate as the solute particles from the solution get deposited on the surface of undissolved solid solute. Since these two processes occur at the same rate, the equilibrium established between dissolved solute and undissolved solute is dynamic.

When a gas is brought in contact with a suitable solvent, the gas keeps on dissolving in the solvent, and eventually, a saturated solution of the gas is formed. At this state, the gas over the liquid surface remains in equilibrium with the dissolved gas in the liquid.

In this state of equilibrium, the gas molecules from the gas phase enter the liquid phase at the same rate as the dissolved gas molecules from the liquid enter the gas phase. Two opposite processes therefore occur at the same rate. For this reason, the equilibrium that forms when a gas remains in equilibrium with its saturated solution is dynamic.

Question 3. Write the expressions of K_c and K_p for the following reactions:

1. 2SO₂(g) + O₂(g) ⇌ 2SO₃(g)

2. 2BrF₅(g)⇌  Br₂(g) + 5F₂(g)

3. 3O₂(g) ⇌ 2O₃(g)

4. 4HCl(g) + O₂(g) ⇌ 2Cl₂(g) + 2H₂O(g)

5. P₄(g) + 3O₂(g) ⇌ P₄O₆(s)

6. CO(g) + 2H₂(g)⇌  CH₃OH(l)

Answer:

1.  \(K_c=\frac{\left[\mathrm{SO}_3\right]^2}{\left[\mathrm{SO}_2\right]^2\left[\mathrm{O}_2\right]} ; K_p=\frac{p_{\mathrm{SO}_3}^2}{p_{\mathrm{SO}_2}^2 \times p_{\mathrm{O}_2}}\)

2.  \(K_c=\frac{\left[\mathrm{Br}_2\right]\left[\mathrm{F}_2\right]^5}{\left[\mathrm{BrF}_5\right]^2} ; K_p=\frac{p_{\mathrm{Br}_2} \times p_{\mathrm{F}_2}^5}{p_{\mathrm{BrF}_5}^2}\)

3.  \(K_c=\frac{\left[\mathrm{O}_3\right]^2}{\left[\mathrm{O}_2\right]^3} ; K_p=\frac{p_{\mathrm{O}_3}^2}{p_{\mathrm{O}_2}^3}\)

4.  \(K_c=\frac{\left[\mathrm{Cl}_2\right]^2\left[\mathrm{H}_2 \mathrm{O}\right]^2}{[\mathrm{HCl}]^4\left[\mathrm{O}_2\right]} ; K_p=\frac{p_{\mathrm{Cl}_2}^2 \times p_{\mathrm{H}_2 \mathrm{O}}^2}{p_{\mathrm{HCl}}^4 \times p_{\mathrm{O}_2}}\)

5.  \(K_c=\frac{\left[\mathrm{P}_4 \mathrm{O}_6(s)\right]}{\left[\mathrm{P}_4\right]\left[\mathrm{O}_2\right]^3}=\frac{1}{\left[\mathrm{P}_4\right]\left[\mathrm{O}_2\right]^3}\)

∵ [P₄O₆(s)]=1]

⇒  \(K_p=\frac{1}{p_{\mathrm{P}_4} \times p_{\mathrm{O}_2}^3}\)

6.  \(K_c=\frac{\left[\mathrm{CH}_3 \mathrm{OH}(l)\right]}{[\mathrm{CO}]\left[\mathrm{H}_2\right]^2}=\frac{1}{[\mathrm{CO}]\left[\mathrm{H}_2\right]^2}\)

∵ [CH₃OH(l)]=1

⇒ \(K_p=\frac{1}{p_{\mathrm{CO}} \times p_{\mathrm{H}_2}^2}\)

Question 4. Write the expression of K_c the following reactions:

1. 2Ag⁺(aq) + Cu(s) ⇌ Cu²⁺(aq) + 2Ag(s)

2. NH₄NO₃(s) ⇌ N₂O(g) + 2H₂O(g)

3. Au⁺(aq) + 2CN^–(aq) ⇌ [Au(CN)₂]^–(aq)

4. 3Cu(s) + 2NO₃^–(aq) + 8H⁺(aq) ⇌ 3Cu²⁺(aq) + 2NO(g) + 4H₂O(l)

5. Cl₂(g) + 2Br^–(aq) ⇌ Br₂(l) + 2Cl^–(aq)

Answer:

1.  \(K_c=\frac{\left[\mathrm{Cu}^{2+}(a q)\right][\mathrm{Ag}(s)]^2}{\left[\mathrm{Ag}^{+}(a q)\right]^2[\mathrm{Cu}(s)]}=\frac{\left[\mathrm{Cu}^{2+}(a q)\right]}{\left[\mathrm{Ag}^{+}(a q)\right]^2}\)

∵  [Ag(s)]=1 and [Cu(s)]=1

2.  \(K_c=\frac{\left[\mathrm{N}_2 \mathrm{O}(g)\right]\left[\mathrm{H}_2 \mathrm{O}(g)\right]^2}{\left[\mathrm{NH}_4 \mathrm{NO}_3(s)\right]}\)

=\(\left[\mathrm{N}_2 \mathrm{O}(g)\right]\left[\mathrm{H}_2 \mathrm{O}(g)\right]^2\)

∵ [NH₄NO₃(s)]=1

3. \(K_c=\frac{\left[\mathrm{Au}(\mathrm{CN})_2^{-}(a q)\right]}{\left[\mathrm{Au}^{+}(a q)\right]\left[\mathrm{CN}^{-}(a q)\right]^2}\)

4.  \(K_c=\frac{\left[\mathrm{Cu}^{2+}(a q)\right]^3[\mathrm{NO}(g)]^2\left[\mathrm{H}_2 \mathrm{O}(l)\right]^4}{[\mathrm{Cu}(s)]^3\left[\mathrm{NO}_3^{-}(a q)\right]^2\left[\mathrm{H}^{+}(a q)\right]^8}\)

⇒ \(\frac{\left[\mathrm{Cu}^{2+}(a q)\right]^3[\mathrm{NO}(g)]^2}{\left[\mathrm{NO}_3^{-}(a q)\right]^2\left[\mathrm{H}^{+}(a q)\right]^8}\)

∵ Cu(s)=1 and H₂O(l)]=1

5.  \(K_c=\frac{\left[\mathrm{Br}_2(l)\right]\left[\mathrm{Cl}^{-}(a q)\right]^2}{\left[\mathrm{Cl}_2(g)\right]\left[\mathrm{Br}^{-}(a q)\right]^2}=\frac{\left[\mathrm{Cl}^{-}(a q)\right]^2}{\left[\mathrm{Cl}_2(g)\right]\left[\mathrm{Br}^{-}(a q)\right]^2}\)

 ∵ [Br₂(l)]=1

NCERT Solutions Class 11 Chemistry Equilibrium Long Questions & Answers

Question 5. Establish the relation between Kp and Kc for the following: aA + bB₂⇌ IL + mM [where the terms have their significance]
Answer:

⇒  \(K_c=\frac{[L]^l \times[M]^m}{[A]^a \times[B]^b}\)

Where [A],[B],[L] and [M] are Molar Concentrations Of A, B, L, and M At Equilibrium

⇒ \(K_p=\frac{p_L^l \times p_M^m}{p_A^a \times p_B^b}; \text { where } p_A, p_B, p_L \text { and } p_M\)

Partial pressures of A, B, L, and M respectively at equilibrium. Now, p_A = [A]RT, p_B = [B]RT, p_L = [L]RT and P_M = [M]RT.

Putting the values of p_A, p_B, p_L, and PM in the expression of, K_p we have—

⇒ \(K_p=\frac{[L]^l \times[M]^m}{[A]^a \times[B]^b} \times(R T)^{(l+m)-(a+b)}\)

Or \(K_p=K_c \times(R T)^{(l+m)-(a+b)}\)

Question 6. Find the relation between K_p &K_c for the given reactions:

1. NH₃(g) +HCl(g) ⇌NH₄Cl(s)

2. C(s) + CO₂(g) + 2Cl₂(g)⇌2COCl₂(g)

3. ½N₂(g) + O₂(g) ⇌NO₂(g)

4. C(s) + H₂O(g) ⇌CO(g) + H₂(g)

5. Fe(s) + H₂O(g)⇌ FeO(s) + H₂(g)

6. CH₄(g) + H₂O(l) ⇌CO(g) + 3H₂(g)

7. CO(g) + 2H₂(g)⇌ CH₃OH(Z)

Answer:

1. \(\Delta n=0-(1+1)=-2 ; K_p=K_c(R T)^{\Delta n}=K_c(R T)^{-2}\)

2. \(\Delta n=2-(1+2)=-1 ; K_p=K_c(R T)^{\Delta n}=K_c(R T)^{-1}\)

3.  \(\Delta n=1-\left(\frac{1}{2}+1\right)=\left(-\frac{1}{2}\right) ; K_p=K_c(R T)^{\Delta n}=K_c(R T)^{-\frac{1}{2}}\)

4.  \(\Delta n=(1+1)-1=+1 ; K_p=K_c(R T)^{\Delta n}=K_c(R T)\)

5.  \(\Delta n=1-1=0 ; K_p=K_c(R T)^{\Delta n}=K_c\)

6.  \(\Delta n=(1+3)-1=+3 ; K_p=K_c(R T)^{\Delta n}=K_c(R T)^3\)

7. \(\Delta n=0-(1+2)=(-3) ; K_p=K_c(R T)^{\Delta n}=K_c(R T)^{-3}\)

Question 7. At a constant temperature, the equilibrium constant of the reaction

1. N₂(g) + 3H₂(g) ⇌ 2NH₃(g) is K, and that of the reaction

2. ½ N₂(g) + H₂(g) ⇌ NH₃(g) is R.

Explain this difference in K values even though the reactants and products in both the reactions are same.
Answer:

The value of the equilibrium constant of a reaction depends upon the mode of writing the balanced equation of the reaction.

1. N₂(g) + 3H₂(g) ⇌ 2NH₃(g)

Equilibrium constant

⇒ \(K=\frac{\left[\mathrm{NH}_3\right]^2}{\left[\mathrm{~N}_2\right]\left[\mathrm{H}_2\right]^3}\)

2. \(\frac{1}{2} \mathrm{~N}_2(\mathrm{~g})+\frac{3}{2} \mathrm{H}_2(\mathrm{~g}) \rightleftharpoons \mathrm{NH}_3(\mathrm{~g}) ;\)

Equilibrium constant

⇒ \(K_1=\frac{\left[\mathrm{NH}_3\right]}{\left[\mathrm{N}_2\right]^{1 / 2} \times\left[\mathrm{H}_2\right]^{3 / 2}}\)

∴ \(K_1^2=\frac{\left[\mathrm{NH}_3\right]^2}{\left[\mathrm{~N}_2\right]\left[\mathrm{H}_2\right]^3}\) = K

⇒ \(K_1=\sqrt{K}\)

In both reactions 1 and 2 reactants and products are the same, but in the equations of these two reactions, the stoichiometric coefficients of reactants and products are different, resulting in different values of the corresponding equilibrium constant.

Question 8. If the value of the equilibrium constant of the reaction 2SO₂(g) + O₂(g)→2SO₃(g) is K, then what will be the lues of equilibrium constants of the following reactions?

1. 4SO₂(g) + 2O₂(g) ⇌4SO₃(g)
2. 2SO₃(g) ⇌ 2SO₂(g) + O₂(g)
3. SO₂(g) + ½O₂(g) ⇌ SO₃(g)
4. SO₃(g) ⇌ SO₂(g) + ½O₂(g)

Answer:

⇒ \(2 \mathrm{SO}_2(g)+\mathrm{O}_2(g) 2 \mathrm{SO}_3(g) ; K=\frac{\left[\mathrm{SO}_3\right]^2}{\left[\mathrm{SO}_2\right]^2\left[\mathrm{O}_2\right]}\)

1.  \(\text { (I) } 4 \mathrm{SO}_2(\mathrm{~g})+2 \mathrm{O}_2(\mathrm{~g})\rightleftharpoons 4 \mathrm{SO}_3(\mathrm{~g})\)

Equilibrium constant = \(\frac{\left[\mathrm{SO}_3\right]^4}{\left[\mathrm{SO}_2\right]^4\left[\mathrm{O}_2\right]^2}=K^2\)

2.  2SO₃(g) ⇌ 2SO₂(g) + O₂(g)

Equilibrium constant =\(\frac{\left[\mathrm{SO}_2\right]^2\left[\mathrm{O}_2\right]}{\left[\mathrm{SO}_3\right]^2}=\frac{1}{K}\)

3.  SO(g)+½O₂(g)⇌ SO₃(g);

Equilibrium constant = \(\frac{\left[\mathrm{SO}_3\right]}{\left[\mathrm{SO}_2\right]\left[\mathrm{O}_2\right]^{1 / 2}}=\sqrt{\mathrm{K}}\)

4.  SO₃(g) ⇌ SO₂(g) +½ O(g)

Equilibrium constant = [SO₂][O₂]^½/[SO₃]

= \(\frac{1}{\sqrt{K}}\)

Equilibrium Chapter 7 Long Answer Questions Class 11

Question 9. A few reactions and their equilibrium constants are given:

1. A ⇌ B + C; K_c = 2;
2. C ⇌ B +D; K_c  = 3
3. D ⇌ B +E; K_c  = 4.

Find the equilibrium constant ofthe reaction, A ⇌3B +E

Answer:

1. \(K_c=2=\frac{|B|[C \mid}{|A|}\)

2. \(K_c=3=\frac{[B \| D]}{[C]}\)

3. \(K_c=4=\frac{[B][E]}{[D]}\)

For the reaction A ⇌ 3B + E

Equilibrium constant K_c=  \(\frac{[B]^3[E]}{[A]}\) ……………………..(1)

Multiplying equilibrium constants of reactions (1),(2)and (30), we have 2× 3× 4

= \(\frac{[B \mid[C]}{\mid A]} \times \frac{[B][D]}{[C]} \times \frac{[B] \mid E]}{[D]}\)

Or,  24 = \(\frac{[B]^3[E]}{[A]}\)…………………….(24)

From the equations (1) and (2), we get  K_c =  24.

Therefore, the equilibrium constant for the reaction A ⇌ 3B + E is 24

Question 10. If the values of Kc for the reactions, A + 2B ⇌ C and C ⇌ 2D are 2 and 4, respectively, then what will be the value of  K_c for the reaction, 2D ⇌ A + 2B

Answer:

A + 2B ⇌ C; K_c = 2 = \(\frac{[C]}{[A][B]^2}\) ………………(1)

C ⇌ 2D ; K_c = 4 =  \(\frac{[D]^2}{[C]}\) ………………(2)

Adding equations 11 1 and [2), A + 26 s=± 2D ………………(3)

The equilibrium constant for equation (3)= Product of The equilibrium constants for reactions (1) and (2)

⇒ \(=\frac{[D]^2}{[A][B]^2}=2 \times 4=8\)

The equilibrium constant For the reaction 2D ⇒ A + 2B, the equilibrium constant = reciprocal of the equilibrium constant for reaction (3)

⇒  \(\frac{1}{8}=0.125\)

Question 11. For the reaction A + B C + D, the equilibrium constant is K. What would be the value of the reaction quotient (Q) when the reaction just starts and when it reaches equilibrium?
Answer:

For the given reaction, the equilibrium constant,

⇒ \(K=\frac{[C]_{e q} \times[D]_{e q}}{[A]_{e q} \times[B]_{e q}} \text { where }[A]_{e q},[B]_{e q},[C]_{e q}\)

[D]_eq are the equilibrium concentrations of A, B, C, and D respectively.

For the given reaction, the reaction quotient (Q) at any moment during the reaction.

⇒ \(Q=\frac{[C] \times[D]}{[A] \times[B]} ; \text { where }[A],[B],[C] \text { and }[D]\)

Are the molar concentrations of.A, B, C, and D respectively at the moment under consideration.

1. Initially: [C] = 0, [D] = 0. Therefore, Q = 0.

2.  At The Equilibrium state;

⇒ \([A]=[A]_{e q},[B]=[B]_{e q}\)

⇒ \([C]=[C]_{e q} \text { and }[D]=[D]_{e q}\)

Hence, Q = K

Question 12. Consider the reaction, A(g) + 2B(g) 2D(g) + 3E(g) + heat, and state how the following changes at equilibrium will affect the yield of the product, D(g)— Temperature is increased, Pressure is increased at a constant temperature, Some amount of E (g) is removed from the reaction system at constant temperature and volume, and Some amount of D(g) is added to the reaction system, keeping temperature and volume constant.
Answer:

The reaction is exothermic. So, the increasing temperature at the equilibrium of the reaction will cause the equilibrium to shift to tire left. This decreases the yield of D(g). As a result, the concentration of D(g) at the new equilibrium will be lower than that at the original equilibrium.

The reaction involves an increase in the number of gas molecules [Δn = (2 + 3)-(l + 2) =+2] in the forward direction. Therefore, at a constant temperature, if the pressure is increased at the equilibrium of the reaction, then, according to Le Chatelier’s principle, the equilibrium will shift to the left. As a result, the yield of D(g) will decrease and the concentration of D(g) at the new equilibrium will be lower than that at the original equilibrium.

At constant temperature and volume, if some amount of E(g) [product] is removed from the reaction system, then, according to Le Chatelier’s principle, the equilibrium of the reaction will shift to the right. As a result, the yield of D(g) will increase, and the concentration of D(g) will increase. Thus, the concentration of D(g) at the new equilibrium will be more than that at the original equilibrium.

At constant temperature and volume, if some amount of D(g) [product] is added to the reaction system at equilibrium, then, according to Le Chatelier’s principle, the equilibrium will shift to the left. As a result, the yield of D(g) will decrease. However, the concentration of D(g) at the new equilibrium will be greater than that at the original equilibrium.

Question 13. Consider the following reactions; What will be the effect on the following if the temperature is increased?

1. The equilibrium constant
2. The position of equilibrium
3. The yield of products.

Answer:

1. The reaction is endothermic as ΔH > 0.

As the reaction is endothermic, the value of its equilibrium constant will increase with the rise in temperature

According to Le Chatelier’s principle, a rise in Na₂CO₃ is a salt of strong base NaOH and weak acid H₂CO₂.

In its aqueous solution, Na₂CO₃ dissociates completely and forms Na⁺ and CO₃ ions. In water, COl- is a stronger base than HaO, and hence it reacts with water, forming OH^– and HCO₂ ions. the temperature at the equilibrium of an endothermic.

Reaction shifts the equilibrium to the right. As a result, the yields of the products increase.

2. The reaction is exothermic as ΔH < 0.

As the reaction is exothermic, the value of its equilibrium constant will decrease with the temperature rise. According to Le Chatelier’s principle, increasing temperature at the equilibrium of an exothermic reaction shifts the equilibrium to the left. Consequently, the yields of the products decrease.

Class 11 Chemistry Equilibrium Long Answer Solutions

Question 14. For these reactions, predict the effect on the following if pressure is increased at equilibrium Position of equilibrium, Yield of the products.
Answer:

The reaction involves no change in volume. Therefore, pressure has no effect either on the position of the equilibrium or on the yield of the product.

The reaction involves a decrease in volume in the forward direction. So, at a constant temperature increasing pressure at the equilibrium of the reaction favors the shifting of equilibrium to the right, thereby increasing the yield of the product.

The reaction involves a decrease in volume in the reverse direction. So, at constant temperature, increasing pressure at the equilibrium of the reaction shifts the equilibrium to the left, thereby decreasing the yield ofthe product

Question 15. At constant temperature, in a closed vessel, the following equilibrium is established during the decomposition of

NH₄Cl(S); NH₄Cl(s)⇌NH₃(g) + HCl(g).

If pressure of. the equilibrium mixture =P and value of equilibrium =K , then show that

⇒ \(P=2 \sqrt{K_p} \text {. }\)

Answer 

Total number of moles at equilibrium = x + x = 2x

∴ \(p_{\mathrm{NH}_3}=\left(\frac{x}{2 x}\right) P ; p_{\mathrm{HCl}}=\left(\frac{x}{2 x}\right) P\)

∴ \(K_p=p_{\mathrm{NH}_3} \times p_{\mathrm{HCl}}=\left(\frac{x}{2 x}\right) P \times\left(\frac{x}{2 x}\right) P=\frac{p^2}{4}\)

∴ \(K_p=\frac{P^2}{4} \quad \text { or, } P^2=4 K_p\)

∴ \(P=2 \sqrt{K_p}\)

Question 16. A weak tribasic acid, H3A, in its aqueous solution, ionizes in the following three steps: 

1. H₃A(aq) + H₂O(l) ⇌ H₃O+(aq)+ H₂A^–(aq)
2. H₂A^–(aq) + H₂O(l) ⇌ H₃O+(aq) + HA^2-(aq)
3. HA^2-(aq) + H₂O(l) ⇌ H₃O+(aq) + A^3-(aq)

If the ionization constants of the steps are K₁, K₂, and K₃ respectively, then determine the overall ionization constant of HgA.

Answer:

Step – 1:  \(K_1=\frac{\left[\mathrm{H}_3 \mathrm{O}^{+}\right]\left[\mathrm{H}_2 \mathrm{~A}^{-}\right]}{\left[\mathrm{H}_3 \mathrm{~A}\right]} \text {; }\)

Step – 2: \( K_2=\frac{\left[\mathrm{H}_3 \mathrm{O}^{+}\right]\left[\mathrm{HA}^{2-}\right]}{\left[\mathrm{H}_2 \mathrm{~A}^{-}\right]}\)

Step – 3: \(K_3=\frac{\left[\mathrm{H}_3 \mathrm{O}^{+}\right]\left[\mathrm{A}^{3-}\right]}{\left[\mathrm{HA}^{2-}\right]}\)

The equation for the overall ionisation of H₃A is:

⇒ \(\mathrm{H}_3 \mathrm{~A}(a q)+3 \mathrm{H}_2 \mathrm{O}(l) \rightleftharpoons \mathrm{A}^{3-}(a q)+3 \mathrm{H}_3 \mathrm{O}^{+}(a q)\)

If the overall ionization constant of H₃A is K, then

⇒ \(K=\frac{\left[\mathrm{A}^{3-}\right]\left[\mathrm{H}_3 \mathrm{O}^{+}\right]^3}{\left[\mathrm{H}_3 \mathrm{~A}\right]}\)

Multiplying ionization constants of steps 1,2 and 3

We have, \(K_1 \times K_2 \times K_3=\frac{\left[\mathrm{A}^{3-}\right]\left[\mathrm{H}_3 \mathrm{O}^{+}\right]^3}{\left[\mathrm{H}_3 \mathrm{~A}\right]}\)

Therefore, K = K₁ × K₂ × K₃

Question 17. Between 0.1(M) and 0.01(M) acetic acid solutions which one will have a higher pH, and why?
Answer:

In an aqueous solution of a weak monoprotic add

Example CH₃COOH )

⇒  \(\left[\mathrm{H}_3 \mathrm{O}^{+}\right]=\sqrt{c \times K_a}\)

Where c = molar concentration of the solution and Ka = ionization constant of the weak acid.

Therefore, in 0.1(M) CH₃COOH solution,

⇒ \(\left[\mathrm{H}_3 \mathrm{O}^{+}\right]=\sqrt{0.1 \times K_a} \mathrm{~mol} \cdot \mathrm{L}^{-1}\) and in 0.01(M) CHgCOOH solution,

[H₃O⁺] \(\sqrt{0.01 \times K_a} \mathrm{~mol} \cdot \mathrm{L}^{-1}\)

Hence, the concentration of H₃O⁺ ions in 0.1(M) CH₃COOH solution will be more than that in 0.01(M) CH₆COOH solution.

Therefore, the pH of 0.01 (M) CH₃COOH solution will be greater than that of O.l (M) CH₃COOH solution.

Long Answer Solutions for NCERT Class 11 Chemistry Equilibrium

Question 18. What color change does a blue or red litmus paper exhibit when it is put separately in each of the following aqueous solutions? CH₃COONa₂CH₃COONH₄, NH₄Cl
Answer:

An aqueous solution of CH₃COONa is alkaline because in solution CH₃COO^– ions resulting from the complete dissociation of CH₃COONa undergo hydrolysis, thereby increasing the concentration of OH^–. So, if a red litmus paper is dipped into this solution, it will turn blue

In its aqueous solution, CH₃COONH₄ dissociates completely forming NH⁺(aqr) and CH₃COO^–(aq) ions. Both these ions undergo hydrolysis in water. The important fact is that in water the strength of CH₃COO^– ion as a base and the strength of NH₂ ion as an acid are the same. Consequently, the concentration of OH^– ions produced due to hydrolysis of CH₃COO^– ions:

⇒ \(\left[\mathrm{CH}_3 \mathrm{COO}^{-}(a q)+\mathrm{H}_2 \mathrm{O}(l) \rightleftharpoons \mathrm{CH}_3 \mathrm{COOH}(a q)+\mathrm{OH}^{-}(a q)\right]\)

Almost the same as the concentration of H₃O⁺ ions produced due to hydrolysis of NH^– ions:

⇒ \(\left[\mathrm{NH}_4^{+}(a q)+\mathrm{H}_2 \mathrm{O}(l) \rightleftharpoons \mathrm{NH}_3(a q)+\mathrm{H}_3 \mathrm{O}^{+}(a q)\right]\)

As a result, an aqueous solution of CH₃COONH₄ is neutral. So, if a litmus paper is dipped into this solution, it will not exhibit any color charge.

In its aqueous solution, NH₄Cl dissociates completely forming NH₂(aq) and Cl^–(aq). NH₂ ions so formed undergo hydrolysis and thereby increase the concentration of H₃O⁺ ions in the solution. As a result, an aqueous solution of NH₄Cl is acidic. Therefore, if a blue litmus paper is dipped into this solution, its color will change to red.

Question 19. Arrange the following aqueous solutions in order of their increasing pH values: Na₂CO₃, CH₃COONH₄, and CuSO₄.
Answer:

Na₂CO₃ is a salt of strong base NaOH and weak acid H₂CO₂. In its aqueous solution, Na₂CO₃ dissociates completely and forms Na⁺ and CO₃^2- ions. In water, CO₃^2- is a stronger base than HaO, and hence it reacts with water, forming OH^– and HCO^–₃ ions.

This results in an increase in the concentration of OH ions in the solution of Na₂CO₃ and makes the solution alkaline.

In its aqueous solution, CuSO₄ dissociates completely, forming [Cu(H₂O)₆]₂⁺ and SO^– ions. SO^–ion, being a conjugate base of strong acid H₂SO₄, is a very weak base and cannot react with water.

In [Cu(H₂O)g]²⁺, the charge density of the Cu²⁺ ion is very high, and consequently, H₂O molecules bonded to the Cu²⁺ ion get polarized.

This causes the weakening of the O — H bonds in the H₂O molecule. Consequently, the O — H bond gets ionized easily, thereby forming an H+ ion. This H+ ion is then accepted by H₂O, which forms the H₃O⁺ ion.

⇒ [Cu(H₂O)6]²⁺(aq) + H₂O(l) ⇌ [Cu(H₂O)₅OH]⁺(aq) + H₃O⁺(aq)

Therefore, the hydrolysis of CuSO₄ in its solution increases the concentration of H₃O⁺ ions, thereby making the solution acidic. So, the increasing order of pH values of the given aqueous solutions: CuSO₄ < CH₃COONH₄ < Na₂CO₃

Question 20. Which of the following are buffer solutions? Give reasons:

1. 100 mL 0.1 (M)NH₃ + 50 mL 0.1(M) HCI
2. 100 mL 0.1 (M)CH₃COOH + 50 m L 0.2 (M) NaOH
3. 100 mL 0.1 (M) CH₃COOH +100 mL 0.15 (M) NaOH
4. 100 mL 0.1 (M) CH₃COONa +25mL 0.1(M) HCI
5. 50 mL 0.2 (M) NH₄Cl + 50 mL 0.1 (M) NaOH

Answer:

1. 100 mL of 0.1(M) NH₃ = O.Olmol of NH₃ and 50mL of 0.1(M) HCI = 0.005mol of HCl. In the mixed solution, 0.005 mol of HCl reacts completely with the same amount of NH₃, forming 0.005 mol of NH₄Cl, and 0.005 mol of NH₃ remains in the solution. Therefore, the mixed solution contains weak base NH₃ and its salt NH₄Cl. Hence, it is a buffer solution.

2. 100mL of 0.1(M) CH₃COOH = 0.01 mol of CH₃COOH and 50mL of 0.2 (M) NaOH = 0.01 mol of NaOH. In the mixed solution, 0.01 mol of CH₃COOH reacts completely with 0.01 mol of NaOH, forming 0.01 mol of CH₃COONa. Therefore, the mixed solution is a solution of CH₃COONa. Hence, it is not a buffer solution

3.100mL of 0.1 (M) CH₃COOH = 0.01 mol of CH₃COOH and 100mL of 0.15(M) NaOH = 0.015 mol of NaOH. In the mixed solution, 0.01 mol CH₃COOH reacts completely with 0.01 mol of NaOH, forming 0.01 mol of CH₃COONa, and 0.005 mol of NaOH remains in the solution. Therefore, the mixed solution is a solution of NaOH. Hence, it cannot be a buffer solution.

4. 100mL of 0.1(M) CH₃COONa = O.Olmol of CH₃COONa and 25mL of 0.1(M) HCI = 0.0025 mol of HCI. In the mixed solution, 0.0025 mol of HCl reacts completely with the same amount of CH₃COONa, forming CH₃COOH and NaCl.

The number of moles of CH₃COONa remaining in the solution is (0.01- 0.0025) = 7.5 × 10^-3 mol. Therefore, the mixed solution contains CH₃COOH and its salt CH₃COONa. Hence, it is a buffer solution.

5. 50mL of 0.2 (M) NH₄Cl EE 0.01 mol of NH₄Cl and 50mL of 0.1 (M) NaOH = 0.005 mol of NaOH . In the mixed solution, 0.005mol of NaOH reacts completely with the same amount of NH₄Cl, thereby forming NH₃ and NaCl. The number of moles of NH₄Cl left behind in the solution is (0.01-0.005) = 0.005 mol. Therefore, the mixed solution contains NH₃ and NH₄Cl. Hence, it is a buffer solution.

Equilibrium Chapter 7 NCERT Long Answer Questions

Question 21. The buffer capacity of a buffer solution consisting of a weak acid, HA, and its salt, NaA becomes maximum when its pH is 5.0. At this pH, what is the relation between the molar concentrations of HA and NaA? Abo finds the value of a of HA.
Answer:

In the case of a buffer solution consisting of a weak acid and its salt, the buffer capacity of the solution is maximum when pH = pK_a.

It is given that the buffer capacity of the given buffer is maximum when its pH = 5. Therefore, the pK_a ofthe weak acid present in the buffer is 5.

Now, the pH of a buffer solution consisting of a weak acid and its salt is given by

⇒  \(p H=p K_a+\log \frac{[\text { salt }]}{[\text { acid }]}\)

Since, \(p H=p K_a=5, \log \frac{[\text { salt }]}{[\text { acid }]}=0\) , [salt] = [acid]

∴ [NaA]=[HA]

Question 22. At a given temperature, if the solubility product and the
solubility of a sparingly soluble salt M₂X₃ are Ksp and S, respectively, then prove that S \(S=\left(\frac{K_{s p}}{108}\right)^{1 / 5}.\)
Answer:

In its saturated solution, M₂X₃ ionizes partially, forming M₃ (aq) and X₂ (aq) ions. Eventually, the following equilibrium is established.

⇒ \(\mathrm{M}_2 \mathrm{X}_3(s) \rightleftharpoons 2 \mathrm{M}^{3+}(a q)+3 \mathrm{X}^{2-}(a q)\)

If the solubility of M₂X₃ in its saturated solution is S mol.L^-1 , then in the solution [M³⁺] = 2S mol.L^-1 and [X^2-] = 3S mol.L^-1

Therefore, the solubility product of M₂X₃

⇒ \(K_{s p}=\left[\mathrm{M}^{3+}\right]^2\left[\mathrm{X}^{2-}\right]^3=(2 S)^2(3 S)^3=108 S^5\)

∴ \(S=\left(\frac{K_{s p}}{108}\right)^{\frac{1}{5}}\)

Question 23. Find out the equilibrium constant for the reaction, XeO₄(g) + 2HF(g)⇌ XeO₃F₂(g) + HaO(g) Consider K₁ as the equilibrium constant for the reaction, XeF₆(g) + HaO(g) ⇌ XeOF₄(g) + 2HF(g) and K₂ as the equilibrium constant for the reaction, XeO₄(g) + XeF₆(g) ⇌ XeOF₄(g) + XeO₃F₂(g).
Answer:

According to the given condition

⇒ \(K_1=\frac{\left[\mathrm{XeOF}_4\right] \times[\mathrm{HF}]^2}{\left[\mathrm{XeF}_6\right] \times\left[\mathrm{H}_2 \mathrm{O}\right]} \text { and } K_2=\frac{\left[\mathrm{XeOF}_4\right] \times\left[\mathrm{XeO}_3 \mathrm{~F}_2\right]}{\left[\mathrm{XeO}_4\right] \times\left[\mathrm{XeF}_6\right]}\)

∴ \(\text { For } \mathrm{XeO}_4(g)+2 \mathrm{HF}(g) \rightleftharpoons \mathrm{XeO}_3 \mathrm{~F}_2(g)+\mathrm{H}_2 \mathrm{O}(g)\)

Equilibrium constant ,\(K=\frac{\left[\mathrm{XeO}_3 \mathrm{~F}_2\right] \times\left[\mathrm{H}_2 \mathrm{O}\right]}{\left[\mathrm{XeO}_4\right] \times\left[\mathrm{HF}^2\right.}\)

⇒ \(\text { Now, } \frac{K_2}{K_1}=\frac{\left[\mathrm{XeO}_3 \mathrm{~F}_2\right] \times\left[\mathrm{H}_2 \mathrm{O}\right]}{\left[\mathrm{XeO}_4\right] \times[\mathrm{HF}]^2}=K\)

∴ K= \(\frac{K_2}{K_1}\)

Class 11 Chemistry Long Answer Equilibrium Questions and Answers

Question 24.  At a particular temperature, for the reaction, aA + bB dC + cD, the equilibrium constant is K. Find out the equilibrium constants for the following reactions at the same temperature.

1. m a A +  m b B m d C+m c D

2. \(\frac{1}{m} a A+\frac{1}{m} b B\frac{1}{m} d C+\frac{1}{m} c D\)

Answer:

For the reaction, aA + bB ⇌ dC+cD the equilibrium constant

⇒ \(K=\frac{[C]^d \times[D]^c}{[A]^a \times[B]^b}\)

1. Now,  For the reaction maA + mbB ⇌ mdC + mcD equilibrium constant,

⇒ \(K_1=\frac{[C]^{m d} \times[D]^{m c}}{[A]^{m a} \times[B]^{m b_3}}\)

= \(\left\{\frac{[C]^d \times[D]^c}{[A]^a \times[B]^b}\right\}^m=K^m\)

2. For the reaction

⇒  \(\frac{1}{m} a A+\frac{1}{m} b B \rightleftharpoons \frac{1}{m} d C+\frac{1}{m} c D\) equilibrium constant,

⇒ \(K_2=\frac{[C]^{d / m} \times[D]^{c / m}}{[A]^{a / m} \times[B]^{b / m}}\) \(=\left\{\frac{[C]^d \times[D]^c}{[A]^a \times[B]^b}\right\}^{1 / m}\)

=\((K)^{1 / m}\)

Question 25. State the nature of aqueous solutions containing the following ions with reason:

1. NH⁺₄,
2. F^–
3. Cl^–.

Answer:

1. NH₄⁺:

NH₄⁺ ion is the conjugate acid of a weak base, NH₃. In an aqueous solution, NH₂ is stronger than H₂O [weak Bronsted acid]. Hence, in an aqueous solution, NH₂ ion reacts with water to produce H₃0+ ions, leaving the die solution acidic.

NH⁺(aq) + H₂O(l) ⇌ NH₃(aq) + H₃O⁺(aq)

2. F^–:

F^– ion is the conjugate base of a weak acid, HF. F^– is stronger titan H₂O [weak Bronsted base] in aqueous solution. For this reason, in an aqueous solution, the F^– ion reacts with water to give OH^– ions, and as a result, the solution becomes basic.

⇒  \(\mathrm{F}^{-}(a q)+\mathrm{H}_2 \mathrm{O}(l) \rightleftharpoons \mathrm{HF}(a q)+\mathrm{OH}^{-}(a q)\)

3. Cl^–:

Cl^– is the die conjugate base of strong acid, HCl. Hence, it is very weak and cannot react with water. Consequently, the die aqueous solution of Cl^– is neutral.

NCERT Class 11 Equilibrium Long Questions

Question 26. The solubility of zinc phosphate in water is S mol. L^-1 . Derive the mathematical expression of the solubility product of the compound.
Answer:

The following equilibrium is established by zinc phosphate, [Zn3(P04)2] in its saturated aqueous solution.

⇒ \(\mathrm{Zn}_3\left(\mathrm{PO}_4\right)_2(s) \rightleftharpoons 3 \mathrm{Zn}^{2+}(a q)+2 \mathrm{PO}_4^{3-}(a q)\)

∴ \(K_{s p}=\left[\mathrm{Zn}^{2+}\right]^3 \times\left[\mathrm{PO}_4^{3-}\right]^2\)

As given, the solubility of Zn₃(PO₄)₂ is S mol. L^-1 .

Hence, \(\left[\mathrm{Zn}^{2+}\right]=3 S \mathrm{~mol} \cdot \mathrm{L}^{-1} \text { and }\left[\mathrm{PO}_4^{3-}\right]=2 S \mathrm{~mol} \cdot \mathrm{L}^{-1}\)

∴ K_sp = (3S)³ × (2S)²= 108 S⁵; this is the mathematical expression of the solubility product of zinc phosphate.

Question 27. When H₂S gas Is passed through an acidified solution of Cu²⁺ and Zn²⁺, only CuS is precipitated—why?
Answer:

H₂S is a very weak acid. In its aqueous solution, only a small fraction of it ionizes to produce H₃O⁺ and S^2- ions

⇒\(\left[\mathrm{H}_2 \mathrm{~S}(a q)+2 \mathrm{H}_2 \mathrm{O}(l) \rightleftharpoons 2 \mathrm{H}_3 \mathrm{O}^{+}(a q)+\mathrm{S}^{2-}(a q)\right]\)

In an acidified solution of H₂S, due to the common ion (H₃O⁺) effect, the ionization of H₂S is further reduced, and as a result, the concentration of S^2- ions becomes extremely low.

When H₂S gas is passed through an acidified solution of Cu²⁺ and Zn²⁺ ions, the concentration of S^-2 ions becomes so low that only the product of the concentrations of Cu²⁺ and S^2- ions exceeds the solubility product of CuS. However, the product of the concentrations of Zn²⁺ and S^2- ions lies well below the value of the solubility product of ZnS. This is why only CuS is precipitated in preference to ZnS.

Question 28. Why is the aqueous solution of Cu(NO₃)₂ acidic?
Answer:

Being a strong electrolyte, Cu(NO₃)₂ dissociates almost completely in its aqueous solution to form [Cu(H₂O)₆]²⁺ and NO₂ ions. In the solution, H₂O also ionizes slightly to form H₃O⁺ and OH^– ions

Cu(NO₃)₂(aq) + 6H₂O(l) → [Cu(H₂O)g]₂+(aq) + 2NO(aq)

2H₂O(l) ⇌  + H₃O⁺(aq) + OH

NO^–₃ is the conjugate base of a strong acid, HNO₃. Hence it is a very weak base. So, NO₂ ions cannot react with water. On the other hand, since the charge density of Cu²⁺ ion in the cationf[Cu(H₂O)₆]⁺² is very high, the H₂O molecules attached to it get polarised, and their O—H bonds become weaker.; These O —H bonds dissociate to produce H+ ions, which are accepted by H₂O to give H₃O⁺ ions.

Cu(H₂O)₆]2+(aq) + H₂O(l) ⇌  [Cu(H₂O)₅OH]⁺(aq) + H₃O⁺(aq)

As a result, the concentration of H₃O⁺ ions in the aqueous solution of Cu(NO₃)₂ becomes higher than that of OH- ions (from H₂O), and consequently, the solution becomes acidic.

Equilibrium Chapter 7 Long Answer Explanation Class 11

Question 29. Despite being a neutral salt, the aqueous solution of Na₂CO₃ is alkaline—why?
Answer:

1. Na₂CO₃, being a strong electrolyte, dissociates almost completely in aqueous solution, forming Na⁺ and CO₃ ions:

⇒ \(\mathrm{Na}_2 \mathrm{CO}_3(a q) \rightarrow 2 \mathrm{Na}^{+}(a q)+\mathrm{CO}_3^{2-}(a q)\)

2. Water, being a very poor electrolyte, ionizes slightly to form H3O+ and OH- ions:

⇒ \(2 \mathrm{H}_2 \mathrm{O}(l) \rightleftharpoons \mathrm{H}_3 \mathrm{O}^{+}(a q)+\mathrm{OH}^{-}(a q)\)

3. Hydrated Na+ ion (Na⁺(aq) ] is a very weak acid and cannot react with water.

4. CO₃^2- the conjugate base of weak acid HCO₃^–, is a stronger base than H₂O (which is a Bronsted base). Therefore, it reacts with water in aqueous solution, forming the following equilibrium.

⇒ \(\mathrm{CO}_3^{2-}(a q)+\mathrm{H}_2 \mathrm{O}(a q) \rightleftharpoons \mathrm{HCO}_3^{-}(a q)+\mathrm{OH}^{-}(a q)\)

HCO₃^– so formed undergoes ionization

⇒ \(\mathrm{HCO}_3^{-}(a q)+\mathrm{H}_2 \mathrm{O}(l) \rightleftharpoons \mathrm{CO}_3^{2-}(a q)+\mathrm{H}_3 \mathrm{O}^{+}(a q)]\)

But, due to the common ion (CO₂^-3) effect, this ionization occurs to a very small extent.

As a result, [OH^–] in solution is much higher than [H⁺]. So, aqueous solution of Na₂CO₃ is alkaline.

NCERT Class 11 Chemistry Equilibrium Very Short Question And Answers

Question 1. Give examples of two systems involving solid-vapour equilibrium.
Answer:  The equilibrium, solid vapour is found to be established when naphthalene or iodine undergoes sublimation in a closed container.

Question 2. Which of the following is the strongest Bronsted base? CIO^–, ClO₂^–, ClO₃^–, ClO₄^–.
Answer: CIO^– is the strongest Bronsted base

Question 3. The equilibrium established in the evaporation of a liquid at a given temperature is due to the same rate of two processes. What are these two processes?
Answer: The rate of evaporation of the liquid will be equal to the rate of condensation of its vapours at the equilibrium.

Equilibrium Chapter 7 Class 11 Very Short Answer Questions

Read and Learn More NCERT Class 11 Chemistry Very Short Answer Questions

Question 4. In a soda water bottle, CO₂ gas remains dissolved in water under high pressure. Write down the equilibrium established in this case.
Answer: CO₂(gas) CO₂ (solution)

Question 5. pH of an aqueous 0.1 (M) CH₃COOH solution is 2.87. State whether the pH of the solution will decrease or increase if CH₃COONa is added to this solution.
Answer: pH will increase.

Question 6. Which of the following mixtures will act as buffer solution(s)? 

1. 50 mL 0.1 (M) NH₃ + 100 mL 0.025(M) HCl 
2. 100mL 0.05(M) CH₆COOH + 50mL 0.1 (M) NaOH

Answer: 1. Will act as a buffer solution.

Question 7. At a constant temperature and pressure, what is the value of ΔG for a reaction at equilibrium?
Answer: Zero

Question 8. For a chemical reaction, K_c> 1. Will the value of ΔG° for this reaction be negative or positive?
Answer: Negative

Question 9. Find the relation between K and Kc for the following system: 2NaHCO₃(s) Na₂CO₃(s) + CO₂(g) + H₂O(g)
Answer: K_p=K_c(RT)₂

Question 10. The values of the equilibrium constant for a particular reaction at 25°C and 50°C are 0.08 and 0.12 respectively. State whether it is an exothermic or an endothermic reaction.
Answer: Exothermic

NCERT Solutions Class 11 Chemistry Equilibrium VSAQ

Question 11. If ‘mol-L^-1′ and ‘atm’ are the units of concentration and pressure respectively, then what will be the value of K_p/K_c for the reaction, N₂O₄(g) ⇌ 2NO₂(g) at 300K?
Answer: 24.63L.atmmol^-1

Question 12. Give an example of a reaction for which, K_p = K_c = K_x.
Answer: N₂(g) + O₂(g) ⇌ 2NO(g)

Question 13. Consider the reaction: A(s) + 2B₂(g) ⇌ AB₄(g); ΔH<0. At equilibrium, what would be the effect of increasing temperature on the concentration 
Answer: Increases