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NCERT Solutions Class 11 Physics Chapter 12 - Kinetic Theory

Q12.1: Estimate the fraction of molecular volume to the actual volume occupied by oxygen gas at STP. Take the diameter of an oxygen molecule to be 3Å.
Ans: Diameter of an oxygen molecule, d = 3Å
Radius, r  NCERT Solutions Class 11 Physics Chapter 12 - Kinetic Theory   = 1.5 Å = 1.5 × 10–8 cm
Actual volume occupied by 1 mole of oxygen gas at STP = 22400 cm3
Molecular volume of oxygen gas
NCERT Solutions Class 11 Physics Chapter 12 - Kinetic Theory
Where, N is Avogadro’s number = 6.023 × 1023 molecules/mole
 NCERT Solutions Class 11 Physics Chapter 12 - Kinetic Theory
Ratio of the molecular volume to the actual volume of oxygen
NCERT Solutions Class 11 Physics Chapter 12 - Kinetic Theory
= 3.8 × 10–4

Q12.2: Molar volume is the volume occupied by 1 mol of any (ideal) gas at standard temperature and pressure (STP: 1 atmospheric pressure, 0 °C). Show that it is 22.4 litres.
Ans: The ideal gas equation relating pressure (P), volume (V), and absolute temperature (T) is given as:
PV = nRT
Where,
R is the universal gas constant = 8.314 J mol–1 K–1
n = Number of moles = 1
T = Standard temperature = 273 K
P = Standard pressure = 1 atm = 1.013 × 105 Nm–2
 NCERT Solutions Class 11 Physics Chapter 12 - Kinetic Theory
= 0.0224 m3
= 22.4 litres
Hence, the molar volume of a gas at STP is 22.4 litres.

Q12.3: Figure 12.8 shows plot of PV/T versus P for 1.00×10–3 kg of oxygen gas at two different temperatures.
(a) What does the dotted plot signify?
(b) Which is true: T1 > T2 or T1 < T2?
(c) What is the value of PV/T where the curves meet on the y-axis?
NCERT Solutions Class 11 Physics Chapter 12 - Kinetic Theory
(d) If we obtained similar plots for 1.00 ×10–3 kg of hydrogen, would we get the same value of PV/T at the point where the curves meet on the y-axis? If not, what mass of hydrogen yields the same value of PV/T (for low pressure high temperature region of the plot)?
(Molecular mass of H2 = 2.02 u, of O2 = 32.0 u, R = 8.31 J mo1–1 K–1.)
Ans: (a) The dotted plot in the graph signifies the ideal behaviour of the gas, i.e., the ratio NCERT Solutions Class 11 Physics Chapter 12 - Kinetic Theory  is equal. μR (μ is the number of moles and R is the universal gas constant) is a constant quality. It is not dependent on the pressure of the gas.
(b) The dotted plot in the given graph represents an ideal gas. The curve of the gas at temperature T1 is closer to the dotted plot than the curve of the gas at temperature T2. A real gas approaches the behaviour of an ideal gas when its temperature increases. Therefore, T1 > T2 is true for the given plot.
(c) The value of the ratio PV/T, where the two curves meet, is μR. This is because the ideal gas equation is given as:
PV = μRT
 NCERT Solutions Class 11 Physics Chapter 12 - Kinetic Theory
Where,
is the pressure
is the temperature
is the volume
μ is the number of moles
R is the universal constant
Molecular mass of oxygen = 32.0 g
Mass of oxygen = 1 × 10–3 kg = 1 g
R = 8.314 J mole–1 K–1
∴  NCERT Solutions Class 11 Physics Chapter 12 - Kinetic Theory
= 0.26 J K–1
Therefore, the value of the ratio PV/T, where the curves meet on the y-axis, is 0.26 J K–1.
(d) If we obtain similar plots for 1.00 × 10–3 kg of hydrogen, then we will not get the same value of PV/T at the point where the curves meet the y-axis. This is because the molecular mass of hydrogen (2.02 u) is different from that of oxygen (32.0 u).
We have:
 NCERT Solutions Class 11 Physics Chapter 12 - Kinetic Theory
R = 8.314 J mole–1 K–1
Molecular mass (M) of H2 = 2.02 u
m = Mass of H2
NCERT Solutions Class 11 Physics Chapter 12 - Kinetic Theory
= 6.3 × 10–2 g = 6.3 × 10–5 kg
Hence, 6.3 × 10–5 kg of H2 will yield the same value of PV/T.

Q12.4: An oxygen cylinder of volume 30 litres has an initial gauge pressure of 15atm and a temperature of 27 °C. After some oxygen is withdrawn from the cylinder, the gauge pressure drops to 11 atm and its temperature drops to 17 °C. Estimate the mass of oxygen taken out of the cylinder (R = 8.31 J mol–1 K–1, molecular mass of O2 = 32 u).
Ans: Volume of oxygen, V1 = 30 litres = 30 × 10–3 m3
Gauge pressure, P1 = 15 atm = 15 × 1.013 × 105 Pa
Temperature, T1 = 27°C = 300 K
Universal gas constant, R = 8.314 J mole–1 K–1
Let the initial number of moles of oxygen gas in the cylinder be n1.
The gas equation is given as:
NCERT Solutions Class 11 Physics Chapter 12 - Kinetic Theory
But,
Where,
m1 = Initial mass of oxygen
M = Molecular mass of oxygen = 32 g
m1 = n1M = 18.276 × 32 = 584.84 g
After some oxygen is withdrawn from the cylinder, the pressure and temperature reduces.
Volume, V2 = 30 litres = 30 × 10–3 m3
Gauge pressure, P2 = 11 atm = 11 × 1.013 × 105 Pa
Temperature, T2 = 17°C = 290 K
Let n2 be the number of moles of oxygen left in the cylinder.
The gas equation is given as:
P2V2 = n2RT2
 NCERT Solutions Class 11 Physics Chapter 12 - Kinetic Theory
NCERT Solutions Class 11 Physics Chapter 12 - Kinetic Theory
But,
Where, m2 is the mass of oxygen remaining in the cylinder
m2 = n2M = 13.86 × 32 = 453.1 g
The mass of oxygen taken out of the cylinder is given by the relation:
Initial mass of oxygen in the cylinder – Final mass of oxygen in the cylinder
= m1m2
= 584.84 g – 453.1 g
= 131.74 g
= 0.131 kg
Therefore, 0.131 kg of oxygen is taken out of the cylinder.

Q12.5: An air bubble of volume 1.0 cm3 rises from the bottom of a lake 40 m deep at a temperature of 12 °C. To what volume does it grow when it reaches the surface, which is at a temperature of 35 °C?
Ans: Volume of the air bubble, V1 = 1.0 cm3 = 1.0 × 10–6 m3
Bubble rises to height, d = 40 m
Temperature at a depth of 40 m, T1 = 12°C = 285 K
Temperature at the surface of the lake, T2 = 35°C = 308 K
The pressure on the surface of the lake:
P2 = 1 atm = 1 ×1.013 × 105 Pa
The pressure at the depth of 40 m:
P1 = 1 atm + g
Where,
ρ is the density of water = 103 kg/m3
g is the acceleration due to gravity = 9.8 m/s2
P1 = 1.013 × 105  40 × 103 × 9.8 = 493300 Pa
We have:
NCERT Solutions Class 11 Physics Chapter 12 - Kinetic Theory
Where, V2 is the volume of the air bubble when it reaches the surface
 NCERT Solutions Class 11 Physics Chapter 12 - Kinetic Theory
= 5.263 × 10–6 m3 or 5.263 cm3
Therefore, when the air bubble reaches the surface, its volume becomes 5.263 cm3.

Q12.6: Estimate the total number of air molecules (inclusive of oxygen, nitrogen, water vapour and other constituents) in a room of capacity 25.0 m3 at a temperature of 27 °C and 1 atm pressure.
Ans: Volume of the room, V = 25.0 m3
Temperature of the room, T = 27°C = 300 K
Pressure in the room, P = 1 atm = 1 × 1.013 × 105 Pa
The ideal gas equation relating pressure (P), Volume (V), and absolute temperature (T) can be written as:
PV = kBNT
Where,
KB is Boltzmann constant = 1.38 × 10–23 m2 kg s–2 K–1
N is the number of air molecules in the room
NCERT Solutions Class 11 Physics Chapter 12 - Kinetic Theory
= 6.11 × 1026 molecules
Therefore, the total number of air molecules in the given room is 6.11 × 1026.

Q12.7: Estimate the average thermal energy of a helium atom at (i) room temperature (27 °C), (ii) the temperature on the surface of the Sun (6000 K), (iii) the temperature of 10 million Kelvin (the typical core temperature in the case of a star).
Ans: (i) At room temperature, T = 27°C = 300 K
Average thermal energy          
NCERT Solutions Class 11 Physics Chapter 12 - Kinetic Theory
Where k is Boltzmann constant = 1.38 × 10–23 m2 kg s–2 K–1
NCERT Solutions Class 11 Physics Chapter 12 - Kinetic Theory
= 6.21 × 10–21J
Hence, the average thermal energy of a helium atom at room temperature (27°C) is  6.21 × 10–21 J.
(ii) On the surface of the sun, T = 6000 K
Average thermal energy
NCERT Solutions Class 11 Physics Chapter 12 - Kinetic Theory 
= 1.241 × 10–19 J
Hence, the average thermal energy of a helium atom on the surface of the sun is 1.241 × 10–19 J.
(iii) At temperature, T = 107 K
Average thermal energy
 NCERT Solutions Class 11 Physics Chapter 12 - Kinetic Theory
NCERT Solutions Class 11 Physics Chapter 12 - Kinetic Theory
= 2.07 × 10–16 J
Hence, the average thermal energy of a helium atom at the core of a star is 2.07 × 10–16 J.

Q12.8: Three vessels of equal capacity have gases at the same temperature and pressure. The first vessel contains neon (monatomic), the second contains chlorine (diatomic), and the third contains uranium hexafluoride (polyatomic). Do the vessels contain equal number of respective molecules? Is the root mean square speed of molecules the same in the three cases? If not, in which case is vrms the largest?
Ans: Yes. All contain the same number of the respective molecules.
No. The root mean square speed of neon is the largest.
Since the three vessels have the same capacity, they have the same volume.
Hence, each gas has the same pressure, volume, and temperature.
According to Avogadro’s law, the three vessels will contain an equal number of the respective molecules. This number is equal to Avogadro’s number, N = 6.023 × 1023.
The root mean square speed (vrms) of a gas of mass m, and temperature T, is given by the relation:
 NCERT Solutions Class 11 Physics Chapter 12 - Kinetic Theory
Where, k is Boltzmann constant
For the given gases, k and T are constants.
Hence vrms depends only on the mass of the atoms, i.e.,
 NCERT Solutions Class 11 Physics Chapter 12 - Kinetic Theory
Therefore, the root mean square speed of the molecules in the three cases is not the same. Among neon, chlorine, and uranium hexafluoride, the mass of neon is the smallest. Hence, neon has the largest root mean square speed among the given gases.

Q12.9: At what temperature is the root mean square speed of an atom in an argon gas cylinder equal to the rms speed of a helium gas atom at – 20 °C? (atomic mass of Ar = 39.9 u, of He = 4.0 u).
Ans: Temperature of the helium atom, THe = –20°C= 253 K
Atomic mass of argon, MAr = 39.9 u
Atomic mass of helium, MHe = 4.0 u
Let, (vrms)Ar be the rms speed of argon.
Let (vrms)He be the rms speed of helium.
The rms speed of argon is given by:
NCERT Solutions Class 11 Physics Chapter 12 - Kinetic Theory......(i)
Where,
R is the universal gas constant
TAr is temperature of argon gas
The rms speed of helium is given by:
NCERT Solutions Class 11 Physics Chapter 12 - Kinetic Theory
It is given that:
(vrms)Ar = (vrms)He
NCERT Solutions Class 11 Physics Chapter 12 - Kinetic Theory
= 2523.675 = 2.52 × 103 K
Therefore, the temperature of the argon atom is 2.52 × 103 K.

Q12.10: Estimate the mean free path and collision frequency of a nitrogen molecule in a cylinder containing nitrogen at 2.0 atm and temperature 17 °C. Take the radius of a nitrogen molecule to be roughly 1.0 Å. Compare the collision time with the time the molecule moves freely between two successive collisions (Molecular mass of N2 = 28.0 u).
Ans: Mean free path = 1.11 × 10–7 m
Collision frequency = 4.58 × 109 s–1
Successive collision time ≈ 500 × (Collision time)
Pressure inside the cylinder containing nitrogen, P = 2.0 atm = 2.026 × 105 Pa
Temperature inside the cylinder, T = 17°C =290 K
Radius of a nitrogen molecule, r = 1.0 Å = 1 × 1010 m
Diameter, d = 2 × 1 × 1010 = 2 × 1010 m
Molecular mass of nitrogen, M = 28.0 g = 28 × 10–3 kg
The root mean square speed of nitrogen is given by the relation:
NCERT Solutions Class 11 Physics Chapter 12 - Kinetic Theory 
Where,
R is the universal gas constant = 8.314 J mole–1 K–1
 NCERT Solutions Class 11 Physics Chapter 12 - Kinetic Theory
= 508.26 m/s
The mean free path (l) is given by the relation:
 NCERT Solutions Class 11 Physics Chapter 12 - Kinetic Theory
Where,
k is the Boltzmann constant = 1.38 × 10–23 kg m2 s–2K–1
 NCERT Solutions Class 11 Physics Chapter 12 - Kinetic Theory
= 1.11 × 10–7 m
Collision frequency
NCERT Solutions Class 11 Physics Chapter 12 - Kinetic Theory
NCERT Solutions Class 11 Physics Chapter 12 - Kinetic Theory
= 4.58 × 109 s–1
Collision time is given as:
 NCERT Solutions Class 11 Physics Chapter 12 - Kinetic Theory
 = 3.93 × 10–13 s
Time taken between successive collisions:
 NCERT Solutions Class 11 Physics Chapter 12 - Kinetic Theory
 = 2.18 × 10–10 s
Hence, the time taken between successive collisions is 500 times the time taken for a collision.


Old NCERT solutions

Q1: A metre long narrow bore held horizontally (and closed at one end) contains a 76 cm long mercury thread, which traps a 15 cm column of air. What happens if the tube is held vertically with the open end at the bottom? 
Ans: Length of the narrow bore, L = 1 m = 100 cm
Length of the mercury thread, l = 76 cm
Length of the air column between mercury and the closed end, la = 15 cm
Since the bore is held vertically in air with the open end at the bottom, the mercury length that occupies the air space is: 100 – (76 15) = 9 cm
Hence, the total length of the air column = 15 9 = 24 cm
Let h cm of mercury flow out as a result of atmospheric pressure.
∴ Length of the air column in the bore = 24  h cm
And, length of the mercury column = 76 – h cm
Initial pressure, P1 = 76 cm of mercury
Initial volume, V1 = 15 cm3
Final pressure, P2 = 76 – (76 – h) = h cm of mercury
Final volume, V2 = (24  h) cm3
Temperature remains constant throughout the process.
P1V1 = P2V2
76 × 15 = h (24  h)
h2  24h – 1140 = 0
 NCERT Solutions Class 11 Physics Chapter 12 - Kinetic Theory
= 23.8 cm or –47.8 cm
Height cannot be negative. Hence, 23.8 cm of mercury will flow out from the bore and 52.2 cm of mercury will remain in it. The length of the air column will be 24 23.8 = 47.8 cm.

Q2: From a certain apparatus, the diffusion rate of hydrogen has an average value of 28.7 cm3 s–1. The diffusion of another gas under the same conditions is measured to have an average rate of 7.2 cm3 s–1. Identify the gas.
[Hint: Use Graham’s law of diffusion: R1/R2 = (M2/M1)1/2, where R1, R2 are diffusion rates of gases 1 and 2, and M1 and M2 their respective molecular masses. The law is a simple consequence of kinetic theory.]
Ans: Rate of diffusion of hydrogen, R1 = 28.7 cm3 s–1
Rate of diffusion of another gas, R2 = 7.2 cm3 s–1
According to Graham’s Law of diffusion, we have:
 NCERT Solutions Class 11 Physics Chapter 12 - Kinetic Theory
Where,
M1 is the molecular mass of hydrogen = 2.020 g
M2 is the molecular mass of the unknown gas
 NCERT Solutions Class 11 Physics Chapter 12 - Kinetic Theory
32 g is the molecular mass of oxygen. Hence, the unknown gas is oxygen.

Q3: A gas in equilibrium has uniform density and pressure throughout its volume. This is strictly true only if there are no external influences. A gas column under gravity, for example, does not have uniform density (and pressure). As you might expect, its density decreases with height. The precise dependence is given by the so-called law of atmospheres
n2 = n1 exp [-mg (h2h1)/ kBT]
Where n2, n1 refer to number density at heights h2 and h1 respectively. Use this relation to derive the equation for sedimentation equilibrium of a suspension in a liquid column:
n2 = n1 exp [-mg NA(ρ - P′) (h2h1)/ (ρRT)]
Where ρ is the density of the suspended particle, and ρ’ that of surrounding medium. [NA is Avogadro’s number, and R the universal gas constant.] [Hint: Use Archimedes principle to find the apparent weight of the suspended particle.]
Ans: According to the law of atmospheres, we have:
n2 = n1 exp [-mg (h2h1)/ kBT] … (i)
Where,
n1 is the number density at height h1, and n2 is the number density at height h2
mg is the weight of the particle suspended in the gas column
Density of the medium = ρ'
Density of the suspended particle = ρ
Mass of one suspended particle = m'
Mass of the medium displaced = m
Volume of a suspended particle = V
According to Archimedes’ principle for a particle suspended in a liquid column, the effective weight of the suspended particle is given as:
Weight of the medium displaced – Weight of the suspended particle
= mgm'g
NCERT Solutions Class 11 Physics Chapter 12 - Kinetic Theory
Gas constant, R = kBN
NCERT Solutions Class 11 Physics Chapter 12 - Kinetic Theory.......(iii)
Substituting equation (ii) in place of mg in equation (i) and then using equation (iii), we get:
n2 = n1 exp [-mg (h2h1)/ kBT]
= n1 exp [- NCERT Solutions Class 11 Physics Chapter 12 - Kinetic Theory (h2h1) ]
= n1 exp [-NCERT Solutions Class 11 Physics Chapter 12 - Kinetic Theory (h2h1) ]

Q4: Given below are densities of some solids and liquids. Give rough estimates of the size of their atoms:
NCERT Solutions Class 11 Physics Chapter 12 - Kinetic Theory
[Hint: Assume the atoms to be ‘tightly packed’ in a solid or liquid phase, and use the known value of Avogadro’s number. You should, however, not take the actual numbers you obtain for various atomic sizes too literally. Because of the crudeness of the tight packing approximation, the results only indicate that atomic sizes are in the range of a few Å].
Ans:


NCERT Solutions Class 11 Physics Chapter 12 - Kinetic Theory
Atomic mass of a substance = M
Density of the substance = ρ
Avogadro’s number = N = 6.023 × 1023

Volume of each atom
Volume of N number of molecules  … (i)
Volume of one mole of a substance = NCERT Solutions Class 11 Physics Chapter 12 - Kinetic Theory … (ii)
 NCERT Solutions Class 11 Physics Chapter 12 - Kinetic Theory
For carbon:
M = 12.01 × 10–3 kg,
ρ = 2.22 × 103 kg m–3
= 1.29 Å
Hence, the radius of a carbon atom is 1.29 Å.
For gold:
M = 197.00 × 10–3 kg
ρ = 19.32 × 103 kg m–3
NCERT Solutions Class 11 Physics Chapter 12 - Kinetic Theory = 1.59 Å
Hence, the radius of a gold atom is 1.59 Å.
For liquid nitrogen:
M = 14.01 × 10–3 kg
ρ = 1.00 × 103 kg m–3
NCERT Solutions Class 11 Physics Chapter 12 - Kinetic Theory = 1.77 Å
Hence, the radius of a liquid nitrogen atom is 1.77 Å.
For lithium:
M = 6.94 × 10–3 kg
ρ = 0.53 × 103 kg m–3
 NCERT Solutions Class 11 Physics Chapter 12 - Kinetic Theory= 1.73 Å
Hence, the radius of a lithium atom is 1.73 Å.
For liquid fluorine:
M = 19.00 × 10–3 kg
ρ = 1.14 × 103 kg m–3
NCERT Solutions Class 11 Physics Chapter 12 - Kinetic Theory = 1.88 Å
Hence, the radius of a liquid fluorine atom is 1.88 Å.

The document NCERT Solutions Class 11 Physics Chapter 12 - Kinetic Theory is a part of the NEET Course Physics Class 11.
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FAQs on NCERT Solutions Class 11 Physics Chapter 12 - Kinetic Theory

1. What is the Kinetic Theory of Matter?
Ans. The Kinetic Theory of Matter states that all particles of matter are in constant motion, and the temperature of a substance is directly proportional to the average kinetic energy of its particles.
2. How does the Kinetic Theory explain the behavior of gases?
Ans. The Kinetic Theory explains the behavior of gases by stating that gas particles are in constant random motion, and their collisions with each other and the walls of the container result in pressure and volume changes.
3. What is the relationship between temperature and kinetic energy according to the Kinetic Theory?
Ans. According to the Kinetic Theory, the temperature of a substance is directly proportional to the average kinetic energy of its particles. As the temperature increases, the particles move faster and have higher kinetic energy.
4. How does the Kinetic Theory explain the difference in states of matter?
Ans. The Kinetic Theory explains the difference in states of matter by stating that the arrangement and movement of particles vary in solids, liquids, and gases. Solids have particles with low mobility, liquids have particles with moderate mobility, and gases have particles with high mobility.
5. Can the Kinetic Theory be applied to all states of matter?
Ans. Yes, the Kinetic Theory can be applied to all states of matter. It helps in understanding the behavior of particles in solids, liquids, and gases by explaining their motion, energy, and interactions.
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