Previous Year Papers

Download Solved Question Papers Free for Offline Practice and view Solutions Online.

Test Series

Take Zigya Full and Sectional Test Series. Time it out for real assessment and get your results instantly.

Test Yourself

Practice and master your preparation for a specific topic or chapter. Check you scores at the end of the test.

States of Matter

Multiple Choice Questions

Which among the following gases can be liquified easily?

Chlorine
Nitrogen
Oxygen
Hydrogen

If average velocity of a sample of gas molecules at 300 K is 5 cm s^-1, what is RMS velocity of same sample of gas molecules at the same temperature? (Given, α: u: v = 1:1.224: 1.127)

6.112 cm/s
4.605 cm/s
4.085 cm/s
5.430 cm/s

Two closed bulbs of equal volume (V) containing an ideal gas initially at pressure p_i and temperature T₁ are connected through a narrow tube of negligible volume as shown in the figure below. The temperature of one of the bulbs is then raised to T₂. The final pressure p_f is:

$2 straight p subscript straight i open parentheses fraction numerator straight T subscript 1 over denominator straight T subscript 1 plus straight T subscript 2 end fraction close parentheses$
$2 straight p subscript straight i open parentheses fraction numerator straight T subscript 2 over denominator straight T subscript 1 plus straight T subscript 2 end fraction close parentheses$
$2 straight p subscript straight i space open parentheses fraction numerator straight T subscript 1 straight T subscript 2 over denominator straight T subscript 1 plus straight T subscript 2 end fraction close parentheses$
$2 straight p subscript straight i space open parentheses fraction numerator straight T subscript 1 straight T subscript 2 over denominator straight T subscript 1 plus straight T subscript 2 end fraction close parentheses$

532 Views

The intermolecular interaction that is dependent on the inverse cube of the distance between the molecule is:

ion-ion interaction
ion-dipole interaction
London force
London force

667 Views

If Z is a compressibility factor, Vander Waal's equation at low pressure can be written as

$straight Z space equals 1 plus RT over pb$
$straight Z space equals space 1 minus straight a over VRT$
$straight Z space equals space 1 minus pb over RT$
$straight Z space equals space 1 minus pb over RT$

265 Views

For the gaseous state, if most probable speed is denoted by C*, average speed by C and mean square speed by C, then for a large number of molecules the ratios of these speeds are:

$straight C asterisk times colon stack space straight C with bar on top space colon thin space straight C space equals space 1.225 space colon 1.128 space space colon 1$
$straight C to the power of asterisk times space colon thin space straight C with bar on top space colon space straight C space equals space 1.128 space colon thin space 1.225 space colon space 1$
$straight C to the power of asterisk times space colon thin space straight C with bar on top space colon space straight C space equals space 1.28 space colon thin space 1.225 space colon space$
$straight C to the power of asterisk times space colon thin space straight C with bar on top space colon space straight C space equals space 1.28 space colon thin space 1.225 space colon space$

325 Views

The compressibility factor for a real gas at high pressure is

$1 plus RT over pb$
$1$
$1 plus pb over RT$
$1 plus pb over RT$

484 Views

'a' and 'b' are van der Waals constants for gases. Chlorine is more easily liquefied than ethane because :

a and b for Cl₂ > a and b for C₂H₆
a and b for Cl₂ < a and b for C₂H₆
a and Cl₂ < a for C₂H₆ but b for Cl₂ > b for C₂H₆
a and Cl₂ < a for C₂H₆ but b for Cl₂ > b for C₂H₆

257 Views

9.
If 10^–4 dm³ of water is introduced into a 1.0 dm³ flask at 300 K, how many moles of water are in the vapour phase when equilibrium is established?(Given: Vapour pressure of H₂O at 300 K is 3170 P_a; R = 8.314 J K^–1 mol^–1)

5.56 x 10^-3 mol

1.53 x 10^-2 mol

4.46 x 10^-2 mol

4.46 x 10^-2 mol

4.46 x 10^-2 mol

The volume occupied by water molecules in vapour phase is (1-10^-4) dm3, that is approximately (1 x 10^-3)m³
p_vapV = n_H2O (mol)
3170 (pa) x 1 x 10^-3 (m³) - n_H2O(mol) x 8.314 (JK^-1 mol^-1) x 300K

382 Views

10.

Assuming that water vapour is an ideal gas, the internal energy change(∆U) when 1 mol of water is vapourised at 1 bar pressure and 100°C, (Given: Molar enthalpy of vapourisation of water at 1 bar and 373 K = 41 kJ mol^-1 and R = 8.3 J mol^–1K^–1 will be) –

4.100 kJ mol^–1
3.7904 kJ mol^–1
37.904 kJ mol^–1
37.904 kJ mol^–1

162 Views

Previous Year Papers

Test Series

Test Yourself

Multiple Choice Questions

9. If 10–4 dm3 of water is introduced into a 1.0 dm3 flask at 300 K, how many moles of water are in the vapour phase when equilibrium is established?(Given: Vapour pressure of H2O at 300 K is 3170 Pa; R = 8.314 J K–1 mol–1) 5.56 x 10-3 mol 1.53 x 10-2 mol 4.46 x 10-2 mol 4.46 x 10-2 mol