A polyatomic gas molecule has $f$ degrees of freedom. The ratio of its molar specific heats ($C_p/C_v$) is given by:

What is the value of $\frac{R}{{{C_P}}}$ for diatomic gas

Which gas law explains the relationship between the pressure and temperature of a gas at constant volume?

A container holds 1 mole of $O_2$ and 3 moles of $Ne$ at temperature $2T$. Neglecting vibrational modes, what is the total internal energy of the gaseous mixture?

A gas mixture consists of 2 moles of ${{\rm{O}}_2}$ and 4 moles of $Ar$ at temperature $T$. Neglecting all vibrational modes, the total internal energy of the system is

The ratio of two specific heats $\frac{{{C_P}}}{{{C_V}}}$ of $CO$ is

An ideal monoatomic gas of given mass is heated at constant pressure. In this process, the fraction of supplied heat energy used for the increase of the internal energy of the gas is

A gaseous mixture consists of $16g$ of helium and $16g$ of oxygen. The ratio $\frac{{{C_P}}}{{{C_V}}}$ of the mixture is

Calculate the total internal energy of a mixture of 4 moles of diatomic gas (neglecting vibrational modes) and 2 moles of monatomic gas at temperature $T$.

A mixture of two ideal diatomic gases A and B, initially at temperatures $T_A$ and $T_B$ respectively, is allowed to reach thermal equilibrium at constant volume. If $n_A$ and $n_B$ are the number of moles of A and B, what is the final equilibrium temperature?

The specific heat of an ideal gas is