A mixture of n1 moles of diatomic gas and n2 moles of monatomic gas has Cp/Cv = γ = 3/2, then

For one mole of a diatomic gas gamma is equal to

If 2 moles of diatomic gas and 1 mole of monatomic gas are mixed, then the ratio of specific heats for the mixture is

A mixture of ideal gas containing 5 moles of monatomic gas and 1 mole of rigid diatomic gas is initially at pressure P_0 volume V_0 and temperature T_0 . If the gas mixture is adiabatically compressed to a volume V_0//4 , then the correct statement(s) is(are) : (Given R is gas constant)

Consider a mixture of 1 moles of helium gas and 4 moles of oxygen gas (molecules taken to be rigid) as an ideal gas. Its CP/CV value will be:

Consider a mixture of 1 moles of helium gas and 4 moles of oxygen gas (molecules taken to be rigid) as an ideal gas. Its CP/CV value will be:

Consider a mixture of 3 moles of helium gas and 2 moles of oxygen gas (molecules taken to be rigid) as an ideal gas. Its C_P//C_V value will be:

Consider a mixture of n moles of helium gas and 2n moles of oxygen gas (molecules taken to be rigid) as an ideal gas. Its C_(p)//C_(y) value will be:

One mole of monoatomic gas and three moles of diatomic gas are put together in a container. The molar specific heat (in JK​^(-1)"​ mol​ "^(-1) ​) at constant volume is (R = 8.3 J K​^(-1​) " mol"​^(-1​) )

The internal energy of one mole of the diatomic gas at 200 K is

n moles of diatomic gas in a cylinder is at a temperature T . Heat is supplied to the cylinder such that the temperature remains constant but n moles of the diatomic gas get converted into monatomic gas . The change in the total kinetic energy of the gas is