The van der Waals' equation for real gas is:
1. (P + a/V2)(V-b) = RT
2. (P+n2a/V2)(V-nb) = nRT
3. \(P=\frac{nRT}{V-nb}-\frac{an^2}{V^2}\)
4. All of the above
The numerical value of cp -cv is equal to:
1. R
2. R/M
3. M/R
4. None of the above
The compressibility of a gas is less than unity at STP. Therefore:
1. Vm > 22.4 litre
2. Vm < 22.4 litre
3. Vm = 22.4 litre
4. Vm = 44.8 litre
The condition that favour a pure sample of an ideal gas to have pressure of 1 atm and a concentration of
1 mol L-1 is -
(R=0.082 L atm mol-1K-1)
1. At STP
2. When V = 22.4 L
3. When T = 12 K
4. Impossible under any conditions
The ratio among most probable velocity, mean velocity, and root mean square velocity is given by
1. 1:2:3
2. 1:
3.
4.
While He is allowed to expand through a small jet under adiabatic condition heating effect is observed. This is due to the fact that:
1. helium is an inert gas
2. helium is a noble gas
3. helium is an ideal gas
4. the inversion temperature of helium is very low
If a gas expands at constant temperature, it indicates that
1. kinetic energy of molecules decreases
2. pressure of the gas increases
3. kinetic energy of molecules remains the same
4. number of the molecules of gas increases
Internal energy and pressure of a gas per unit volume are related as
1. p= E
2. p = E
3. p=E
4. p = 2E
The gas among the following that can be most steadily liquefied is -
1. NH3
2. Cl2
3. SO2
4. CO2
The correct statement for an ideal gas equation is -
1. n is the number of molecules of a gas.
2. V denotes the volume of 1 mole of the gas.
3. n moles of a gas has a volume V.
4. p is the pressure of the gas when only one mole of the gas is present.