One litre of gas A and two litres of gas B, both having the same temperature 100C and the same pressure 2.5 bar will have the ratio of kinetic energies of their molecules as:
(1) 1:1 (2) 1:2 (3) 1:4 (4) 4:1
An ideal gas is filled in a vessel, then
(1) If it is placed inside a moving train, its temperature increases
(2) Its centre of mass moves randomly
(3) Its temperature remains constant in a moving car
(4) None of these
If P is the pressure of the gas then the KE per unit volume of the gas is:
1.
2.
3.
4.
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
1. 4RT
2. 15RT
3. 9RT
4. 11RT
For an ideal gas V-T curves at constant pressure and are shown in figure. From the figure
1.
2.
3.
4.
4.0 g of a gas occupies 22.4 L at NTP. The specific heat capacity of the gas at constant volume is 5.0 J K-1mol-1. If the speed of sound in this gas at NTP is, then the heat capacity at constant pressure is: (Take gas constant R=8.3 JK-1mol-1)
(a) 8.0 JK-1mol-1
(b) 7.5 JK-1mol-1
(c) 7.0 JK-1mol-1
(d) 8.5 JK-1mol-1
The mean free path of gas A, with molecular diameter equal to 4 Å, contained in a vessel, at a pressure of torr, is 6990 cm. The vessel is evacuated and then filled with gas B, with molecular diameter, equal to 2 Å, at a pressure of torr, the temperature remaining the same. The mean free path of gas B will be
(A) 28 cm
(B) 280 cm
(C) 7 cm
(D) 14 cm
The mean free path of gas molecules depends on:
(\(d=\) molecular diameter)
1. \(d\)
2. \(d^2\)
3. \(d^{-2}\)
4. \(d^{-1}\)
A gas at 27°C temperature and 30 atmospheric pressure is allowed to expand to the atmospheric pressure. If the volume becomes 10 times its initial volume, then the final temperature becomes
1. 100°C
2. 173°C
3. 273°C
4. – 173°C
The equation of state for 5 g of oxygen at a pressure P and temperature T, when occupying a volume V, will be
1.
2.
3.
4.
(where R is the gas constant)