Find the mean free path and the mean time interval between successive collisions of gaseous nitrogen molecules
(a) under standard conditions ,
(b) at temperature `t = 0 ^@C` and pressure `p = 1.0 nPa` (such a pressure can be reached by means of contemporary vacuum pumps).

In a dilute gas at pressure P and temperature T, the mean time between successive collisions of a molecule varies with T as :

How many times does the mean free path of nitrogen molecules exceed the mean distance between the molecules under standard conditions ?

The root mean square of gas molecules at 25 K and 1.5 bar is "100 m s"^(-1) . If the temperature is raised to 100 K and the pressure to 6.0 bar, the root mean square speed becomes

A gaseous mixture of propane and butane of volume 3 litre on complete combustion produces 11.0 litre CO_(2) under standard conditions of temperature and pressure. The ration of volume of butane to propane is:

How does the mean free path lamda and the number of collisions of each molecule per unit time v depend on the absolute temperature of an ideal gas undergoing (a) an isochoric process , (b) an isobaric process ?

Find the mean free path of gas molecules under standard conditions if the Van der Waals constant of this gas is equal to b = 40 ml//mol .

Calculate the ratio of the mean free paths of the molecules of two gases having molecular diameters 1Å and 2Å . The gases may be considered under indentical conditions of temperature pressure and volume.

Calculate the ratio of the mean free paths of the molecules of two gases having molecular diameters 1 A and 2 A . The gases may be considered under identical conditions of temperature, pressure and volume.

Estimate the mean free path and collision frequency of a nitrogen molecule in a cylinder containing nitrogen at 2 atm. And temperature 17^(@) . Take the radius of a nitrogen molecule to be roughly 1.0 Å . Compare the collision time with the time molecule moves freely between two successive collisions. (Molecular mass of nitrogen = 28.0 u).