No heat is added or removed in an adiabatic process

The change in internal energy in a constant pressure process from temperature $$T_1$$ to $$T_2$$ is equal to $$NC_V(T_2-T_1)$$, where $$C_V$$ is the molar specific heat at constant volume and n is the number of moles of the gas

The change in internal energy of the gas and the work done by the gas are equal in magnitude in an adiabatic process

The internal energy does not change in an isothermal process

Match List I with List II and select the correct answer using the codes given the lists. List I List II P. Boltzmann Constant $$1$$. $$[ML^2T^{-1}]$$ Q. Coefficient of viscosity $$2$$. $$[ML^{-1}T^{-1}]$$ R. Plank Constant $$3$$. $$[MLT^{-3}K^{-1}]$$ S. Thermal conducivity $$4$$. $$[ML^2T^{-2}K^{-1}]$$

P-$$4$$, Q-$$2$$, R-$$1$$, S-$$3$$

P-$$3$$, Q-$$1$$, R-$$2$$, S-$$4$$

P-$$3$$, Q-$$2$$, R-$$1$$, S-$$4$$

P-$$4$$, Q-$$1$$, R-$$2$$, S-$$3$$

MCQ Questions for Class 11 Engineering Physics Kinetic Theory Quiz 9

The temperature (T) of one mole of an ideal gas varies with its volume (V) as $$T = -\alpha { V }^{ 3 }+\ \beta { V }^{ 2 }$$, where $$\alpha$$ and $$\beta$$ are positive constants. The maximum pressure of gas during this process is

0%
$$\dfrac { \alpha \beta }{ 2R } $$
0%
$$\dfrac { { \beta }^{ 2 }R }{ 4\alpha }$$
0%
$$\dfrac { (\alpha +\beta )R }{ { 2\beta }^{ 2 } }$$
0%
$$\dfrac { { \alpha }^{ 2 }R }{ { 2\beta } }$$

When an ideal diatomic gas is heated at constant pressure, the fraction of the heat energy supplied which increase the internal energy of gas is?

0%
$$\frac{2}{5}$$
0%
$$\frac{3}{5}$$
0%
$$\frac{3}{7}$$
0%
$$\frac{5}{7}$$

Two identical glass bulbs are interconnected by a thin glass tube at $$0^{\circ}C$$. A gas is filled at N.T.P. in these bulb is placed in ice and another bulb is placed in hot bath, then the pressure of the gas becomes $$1.5\ times$$. The temperature of hot bath will be

0%
$$100^{\circ}$$
0%
$$182^{\circ}C$$
0%
$$256^{\circ}C$$
0%
$$546^{\circ}C$$

A vessel of volume $$0.3 \ { { m }^{ 3 } }$$ contains Helium at $$20.0$$. The average kinetic energy per molecule for the gas is:

0%
$$6.07\times { 10 }^{ -21 }J$$
0%
$$7.3\times { 10 }^{ 3 }J$$
0%
$$14.6\times { 10 }^{ 3 }J$$
0%
$$12.14\times { 10 }^{ -21 }J$$

A monoatomic ideal gas undergoes a process in which the ratio of $$P$$ to $$V$$ at any instant is constant and equal to unity. The molar heat capacity of gas is:

0%
$$1.5\ R$$
0%
$$2.0\ R$$
0%
$$2.5\ R$$
0%
$$0$$

A monoatomic ideal gas, initially at temperature $$T_1$$. is enclosed in a cylinder fitted with a frictionless piston. The gas is allowed to expand adiabatically to temperature $$T_2$$ by releasing the piston suddenly. If $$L_1$$ and $$L_2$$ are the lengths of the gas column before and after expansion respectively, then $$\frac{T_1}{T_2}$$ is given by

0%
$$(\dfrac{L_1}{L_2})^{2/3}$$
0%
$$\dfrac{L_1}{L_2}$$
0%
$$\dfrac{L_2}{L_1}$$
0%
$$(\dfrac{L_2}{L_1})^{2/3}$$

If for a gas $$\dfrac{R}{C_V}=0.67$$, this gas is made up of molecules which are.

0%
Monatomic
0%
Diatomic
0%
Polyatomic
0%
Mixture of diatomic and polyatomic molecules

One Kg of a diatomic gas is at a pressure of $$8\times 10^4$$N/ $$m^{2}$$. The density of the gas is $$4$$kg/ $$m^{3}$$. The energy of the gas due to its thermal motion will be

0%
$$3\times 10^4$$J
0%
$$5\times 10^4$$J
0%
$$6\times 10^4$$J
0%
$$7\times 10^4$$J

The internal energy of one gram of helium at $$100$$K and one atmospheric pressure is?

0%
$$100$$J
0%
$$1200$$J
0%
$$300$$J
0%
$$500$$J

Which one of the following is not an assumption of kinetic theory of gases?

0%
The volume occupied by the molecules of the gas is negligible
0%
The force of attraction between the molecules is negligible
0%
The collision between the molecules are elastic
0%
All molecules have same speed

A vessel of volume V contains a mixture of $$1$$mole of hydrogen and $$1$$ mole of oxygen(both considered as ideal). Let $$f_1(v)dv$$ denote the fraction of molecules with speed between v and $$(v+dv)$$ with $$f_2(v)dv$$, similarly for oxygen. then

0%
$$f_1(v)+f_2(v)=f(v)$$ obeys the Maxwell's distribution law
0%
$$f_1(v), f_2(v)$$ will obey the Maxwell's distribution law separately
0%
Neither $$f_1(v)$$ nor $$f_2(v)$$ will obey the Maxwell's distribution law
0%
$$f_2(v)$$ and $$f_1(v)$$ will be the same

A gas mixture consists of $$2$$ moles of oxygen and $$4$$ moles of Argon at temperature T. Neglecting all vibrational modes, the total internal energy of the system is?

0%
$$4$$RT
0%
$$9$$RT
0%
$$11$$RT
0%
$$15$$RT

If the pressure and the volume of certain quantity of ideal gas are halved, then its temperature

0%
Is doubled
0%
Becomes one-fourth
0%
Remains constant.
0%
Become four times

The average kinetic energy of $$O_2$$ at a particular temperatures is $$0.768$$ eV. The average kinetic energy of $$N_2$$ molecules in eV at the same temperature is?

0%
$$0.0015$$
0%
$$0.0030$$
0%
$$0.048$$
0%
$$0.768$$

Molecular motion shows itself as.

0%
Temperature
0%
Internal energy
0%
Friction
0%
Viscosity

The kinetic energy of $$1$$g molecule of a gas, at normal temperature and pressure, is?

0%
$$0.56\times 10^4$$J
0%
$$2.7\times 10^2$$J
0%
$$1.3\times 10^2$$J
0%
$$3.4\times 10^3$$J

Pressure depends on distance as $$P = \dfrac{\alpha}{\beta} exp (- \dfrac{\alpha z}{k \theta})$$, where $$\alpha, \beta$$ are constants, z is distance, k is Boltzmann's constant, and $$\theta$$ is temperature. The dimensions of $$\beta$$ are

0%
$$M^0L^0T^0$$
0%
$$M^{-1}L^{-1}T^{-1}$$
0%
$$M^0L^2T^0$$
0%
$$M^{-1}L^{2}T^{2}$$

A vessel contains a mixture consisting of m$$_{1}$$ - 7 g of nitrogen (M$$_{1}$$ = 28) and m$$_{2}$$ = 11 g of carbon dioxide (M$$_{2}$$ = 44) at temperature T - 300 K and pressure P$$_{0}$$ = 1 atm. The density of the mixture is

0%
$$1.46g\ per\ litre$$
0%
$$2.567 g \ per \ litre$$
0%
$$3.752 g \ per \ litre$$
0%
$$4.572 g \ per \ litre$$

A gas performs Q work when it expand at constant pressure. During this process heat absorbed by the gas is 4Q. The average number of degrees of freedom for the gas is:

0%
5
0%
6
0%
4
0%
3.5

An ideal gas is initially at $$P_1$$, $$V_1$$ is expanded to $$P_2, V_2$$ and then compressed adiabatically to the same volume $$V_1$$ and pressure $$P_3$$. If W is the net work done by the gas in the complete process which of the following is true.

0%
$$W > 0; P_3 > P_1$$
0%
$$W < 0; P_3 > P_1$$
0%
$$W > 0; P_3 < P_1$$
0%
$$W < 0; P_3 < P_1$$

A vessel contains a mixture consisting of $${m}_{1}=7kg$$ of nitrogen $$\left( { M }_{ 1 }=28 \right) $$ and $${m}_{2}=11g$$ of carbon dioixide $$\left( { M }_{ 2 }=44 \right) $$ at temeprature $$T=300K$$ and pressure $${ P }_{ 0 }=1\quad atm$$. The density of the mixture is:

0%
$$1.446g$$ per litres
0%
$$2.567g$$ per litre
0%
$$3.752g$$ per litre
0%
$$4.572g$$ per litre

The average degree of freedom per molecule for a gas isThe gas performs 25 J of work when it expands at constant pressure. The heat absorbed by the gas is

0%
75 J
0%
100 J
0%
150 J
0%
125 J

A gas thermometer measures the temperature from the variation of pressure of a sample of gas. If the pressure measured at the melting point of lead is $$2.20\ times$$ the pressure measured at the triple point of water find the melting point of lead.

0%
$$600K$$
0%
$$420K$$
0%
$$790K$$
0%
$$510K$$

For a ideal gas.

0%
The change in internal energy in a constant pressure process from temperature $$T_1$$ to $$T_2$$ is equal to $$NC_V(T_2-T_1)$$, where $$C_V$$ is the molar specific heat at constant volume and n is the number of moles of the gas
0%
The change in internal energy of the gas and the work done by the gas are equal in magnitude in an adiabatic process
0%
The internal energy does not change in an isothermal process
0%
No heat is added or removed in an adiabatic process

Match List I with List II and select the correct answer using the codes given the lists.

List I	List II
P. Boltzmann Constant	$$1$$. $$[ML^2T^{-1}]$$
Q. Coefficient of viscosity	$$2$$. $$[ML^{-1}T^{-1}]$$
R. Plank Constant	$$3$$. $$[MLT^{-3}K^{-1}]$$
S. Thermal conducivity	$$4$$. $$[ML^2T^{-2}K^{-1}]$$

0%
P-$$3$$, Q-$$1$$, R-$$2$$, S-$$4$$
0%
P-$$3$$, Q-$$2$$, R-$$1$$, S-$$4$$
0%
P-$$4$$, Q-$$2$$, R-$$1$$, S-$$3$$
0%
P-$$4$$, Q-$$1$$, R-$$2$$, S-$$3$$

An insulated box containing monatomic ideal gas of molar mass M is moving with a uniform speed v. The box suddenly stops and consequently the gas acquires a new temperature. Calculate the change in the temperature of the gas. Neglect heat absorbed by the box.

0%
$$\Delta T=2\dfrac{Mv^2}{3R}$$.
0%
$$\Delta T=\dfrac{Mv^2}{3R}$$.
0%
$$\Delta T=3\dfrac{Mv^2}{3R}$$.
0%
$$\Delta T=4\dfrac{Mv^2}{3R}$$.

A gas molecule of mass $$M$$ at the surface of the earth has kinetic energy equivalent to $${0}^{o}C$$. If it were to go up straight without colliding with any other molecules, how high it would rise? Assume that the height attained is much less than radius of the earth. ($${k}_{B}$$ is Boltzmann constant)

0%
zero
0%
$$\cfrac { 273{ k }_{ B } }{ 2Mg } $$
0%
$$\cfrac { 546{ k }_{ B } }{ 3Mg } $$
0%
$$\cfrac { 819{ k }_{ B } }{ 2Mg } \quad $$

An ideal gas having initial pressure P, volume V and temperature T is allowed to expand adiabatically until its volume becomes $$5.66$$V while its temperature falls to $$T/2$$. How many degrees of freedom do the gas molecules have?

0%
7
0%
$$5$$.
0%
6
0%
8

$$m$$ grams of a gas of molecular weight $$M$$ is flowing in an insulated tube with velocity $$v$$. If the system is suddenly stopped then the rise in its temperature will be (γ= ratio of specific heats, R=universal gas constant, J=Mechanical equivalent of heat)

0%
$$\dfrac {Mv^{2}(\gamma - 1)}{2RJ}$$
0%
$$\dfrac {Mv^{2}\gamma}{2RJ}$$
0%
$$\dfrac {v^{2}}{2Js}$$
0%
$$\dfrac {Mv^{2}(\gamma - 1)}{2MRJ}$$

Two monatomic ideal gases $$1$$ and $$2$$ of molecular masses $$m_1$$ and $$m_2$$ respectively are enclosed in separate containers kept at the same temperature. The ratio of the speed of sound in gas $$1$$ to that in gas $$2$$ is given by.

0%
$$\sqrt{\dfrac{m_1}{m_2}}$$
0%
$$\sqrt{\dfrac{m_2}{m_1}}$$
0%
$$\dfrac{m_1}{m_2}$$
0%
$$\dfrac{m_2}{m_1}$$

Two cylinders contain the same amount of ideal monatomic gas. The same amount of heat is given to two cylinders. If the temperature rise in cylinder A is $$T_0$$ then temperature rise in cylinder B will be :

0%
$$\dfrac{4}{3}T_0$$
0%
$$2T_0$$
0%
$$\dfrac{T_0}{2}$$
0%
$$\dfrac{5}{3}T_0$$

One kg of a diatomic gas is at a pressure of $$8\times {10}^{4}N/{m}^{2}$$. The density of gas is $$4kg/{m}^{2}$$. What is the energy of the gas due to its thermal motion?

0%
$$6\times {10}^{4}J$$
0%
$$7\times {10}^{4}J$$
0%
$$3\times {10}^{4}J$$
0%
$$5\times {10}^{4}J$$

Ratio of $$C_P$$ and $$C_V$$ of gas '$$X$$' is 1.The number of atoms of the gas '$$X$$' present in $$11.2$$ litres of at NTP will be:

0%
$$6.02\times 10^{23}$$
0%
$$5.61\times 10^{23}$$
0%
$$3.01\times 10^{23}$$
0%
$$2.01\times 10^{23}$$

Valency of carbon is

44. From this, we understand that there are ____chemical bond/bonds between the carbon atom and one oxygen atom in the compound-carbon dioxide.

0%
$$1$$
0%
$$2$$
0%
$$3$$
0%
$$4$$

If temperature of body increases by 10%, then increase in radiated energy of the body is :

0%
10 %
0%
40 %
0%
46 %
0%
1000 %

The average thermal energy of a oxygen atom at room temperature $$(27^{o}C)$$

0%
$$4.5\times {10}^{-21}{J}$$
0%
$$6.2 \times {10}^{-21}{J}$$
0%
$$3.4 \times {10}^{-21}{J}$$
0%
$$1.8 \times {10}^{-21}{J}$$

The amount of heat energy required to raise the temperature of $$1\ g$$ of helium in a container of volume $$10L$$, from $$T_{1}\ K$$ to $$T_{2}\ K$$ is ($$N_{a} =$$ Avogadros number, $$k_{B}=$$ Boltzmann constant)

0%
$$\dfrac { 3 }{ 2 } { N }_{ a }{ k }_{ B }\left( { T }_{ 2 }-{ T }_{ 1 } \right) $$
0%
$$\dfrac { 3 }{ 7} { N }_{ a }{ k }_{ B }\left( { T }_{ 2 }-{ T }_{ 1 } \right) $$
0%
$$\dfrac { 3 }{ 4 } { N }_{ a }{ k }_{ B }\left( { T }_{ 2 }-{ T }_{ 1 } \right) $$
0%
$$\dfrac { 3 }{ 8 } { N }_{ a }{ k }_{ B }\left( { T }_{ 2 }-{ T }_{ 1 } \right) $$

The kinetic energy of $$ 1g $$ molecule of a gas at normal temperature and pressure is :

0%
$$1.3$$ x $$10^2 J $$
0%
$$2.7$$ x $$10^2 J $$
0%
$$0.56$$ x $$10^4 J $$
0%
$$3.4$$ x $$10^3 J $$

In an experiment, 1.35 mol of oxygen (O2) are heated at constant pressure starting at 11.0ºC. How much heat must be added to the gas to double its volume?

0%

$$1.12\times 10^4 J$$
0%

$$1.40\times 10^4$$
0%
$$2.12\times 10^4$$J
0%
$$3.12×10^4 J$$

By the ideal gas law, the pressure of $$0.60$$ moles $${NH}_{3}$$ gas in a $$3.00\ L$$ vessel at $${25}^{o}C$$ is, given that $$R=0.082\ L$$ atm $${mol}^{-1}{k}^{-1}$$:

0%
$$48.9\ atm$$
0%
$$4.89\ atm$$
0%
$$0.489\ atm$$
0%
$$489\ atm$$

Mean kinetic energy (or average energy) per gm. of a molecule of a monoatomic gas is given by :

0%
$$\dfrac{3RT}{2}$$
0%
$$\dfrac{kT}{2}$$
0%
$$\dfrac{RT}{3}$$
0%
$$\dfrac{3kT}{2}$$

RMS velocity of an ideal gas at $$27^o C$$ is $$500{m/s}$$, Temperature is increased four times, RMS velocity will become.

0%
$$1000{m/s}$$
0%
$$560{m/s}$$
0%
$$2000m/s$$
0%
None of these

If the total number of $$H_2$$ molecules is double of the $$O_2$$ molecules then the ratio of total kinetic energies pf $$H_2$$ to that of $$O_2$$ at 300 K is :-

0%
1 : 1
0%
1 : 2
0%
2 : 1
0%
1 : 3

Ideal monoatomic gas is taken through a process $$dQ =2dU$$. What is the molar heat capacity for the process? ( where dQ is heat supplied and dU is change in internal energy)

0%
2R
0%
3R
0%
4R
0%
5R

The relation between the ratio of specific heats $$(\gamma)$$ of gas and degree of freedom $$'f'$$ will be :

0%
$$\gamma=f+2$$
0%
$$\dfrac{1}{\gamma}=\dfrac{1}{f}+\dfrac{1}{2}$$
0%
$$f=\dfrac{2}{\gamma-1}$$
0%
$$f=2(\gamma-1)$$

Three particles are situated on a light and rigid rod along Y-axis as shown in the figure. If the system is rotating with angular velocity of $$2 rad/sec$$ about X axis, then the total kinetic energy of the system is :

0%
$$92 J $$
0%
$$184 J $$
0%
$$ 276 J $$
0%
$$46 J $$

The total kinetic energy of 1 mole of $${ N }_{ 2 }$$ at $$27^oC$$ will be approximately:

0%
$$1500J$$
0%
$$1500$$ calorie
0%
$$1500$$ kilo calorie
0%
$$1500$$ erg

The total Kinetic energy of $$1\ mole$$ of $${N}^{}_{2}$$ at $$27^{o}_{}{C}$$ will be approximately :-

0%
$$1500\ J$$
0%
$$15633\ cal$$
0%
$$1500\ kcal$$
0%
$$1500\ erg$$

$$3$$ mole of gas ''X" and $$2$$ moles of gas "Y" enters from end "P" and "Q" of the cylinder respectively. The cylinder has the area of cross section , shown as
under
The length of the cylinder is $$150cm$$. The gas "X" intermixes with gas "Y" at the point . If the molecular weight of the gases X and Y is $$20$$ and $$80$$ respectively, then what will be the distance of point A from Q?

0%
$$75cm$$
0%
$$50cm$$
0%
$$37.5$$
0%
$$90cm$$

How many degrees of freedom the gas molecules have if under STP the gas density $$\rho = 1.3 kg/m^3$$ and the velocity of sound propagation in it is $$330 ms^{-1}$$?

0%
$$3$$
0%
$$5$$
0%
$$7$$
0%
$$8$$

CBSE Questions for Class 11 Engineering Physics Kinetic Theory Quiz 9 - MCQExams.com

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Practice Class 11 Engineering Physics Quiz Questions and Answers

CBSE Questions for Class 11 Engineering Physics Kinetic Theory Quiz 9 - MCQExams.com

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Practice Class 11 Engineering Physics Quiz Questions and Answers

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