The molecules of a gas A travel four times faster than the molecules of gas B at the same temperature. The ratio of molecular weight `(M_A // M_B)` will be

Two monoatomic 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

N molecules, each of mass m of gas A and 2 N molecules each of mass 2m of gas B are containted in the same vessel which is maintained at temperature T. The mean square velocity of molecules of B type is denoted by v^(2) and the mean square velocity of A type is denoted by (omega)^(2) . the omega^(2)//v^(2) is:

Two identical containers A and B with frictionless pistons contain the same ideal gas at the same temperature and the same velocity V. The mass of the gas in A is m_A, and that in B is m_B . The gas in each cylinder is now allowed to expand isothermally to the same final volume 2V. The changes in the pressure in A and B are found to be DeltaP and 1.5 DeltaP respectively. Then

Let barv,v_(rms) and v_p respectively denote the mean speed. Root mean square speed, and most probable speed of the molecules in an ideal monoatomic gas at absolute temperature T. The mass of a molecule is m. Then

Statement-1: The de-Broglie wavelength of a molecules (in a sample of ideal gas ) varies inversely as the square root of absolute temperature Statement 2:The rms velocity of a molecules (in a sample of ideal gas ) depend in temperature.

Statement-1: The total translational kinetic energy of fall the molecules of a given mass of an ideal gas is 1.5 times the product of its pressure and its volume because. Statement-2: The molecules of a gas collide with each other and the velocities of the molecules change due to the collision.

A gaseous mixture enclosed in a vessel of volume V consists of one gram mole of gas A with gamma = (C_(P))/(C_(V)) = (5)/(3) an another gas B with gamma = (7)/(5) at a certain temperature T . The gram molecular weights of the gases A and B are 4 and 32 respectively. The gases A and B do not react with each other and are assumed to be ideal. The gaseous mixture follows the equation PV^(19//13) = constant , in adiabatic process. Find the number of gram moles of the gas B in the gaseous mixture.

Cooking gas container are kept in a lorry moving with uniform speed. The temperature of the gas molecules inside will

Three closed vessels A, B and C are at the same temperature T and contain gases which obey the Maxwellian distribution of velocities. Vessel A contains only O_(2), B only N_(2) and C a mixture of equal quantities of O_(2) and N_(2) . If the average speed of the O_(2) molecules in vessel A is V_(1) , that of the N_(2) molecules in vessel B is V_(2) , the average speed of the O_(2) molecules in vessel C is (where M is the mass of an oxygen molecules)