A gas has molar heat capacity `c=37.55J.mol^-1.K^-1`. In the process pT=constant . Find the number of degrees of freedom of the molecules of the gas.

IF n is the number of degrees of freedom of the molecules of an ideal gas, show that the ratio C_p/C_v is 1+2/n .

The ratio between the specific heats of an ideal gas is gamma . Show that the number of degrees of freedom of the gas molecules is n=2/(gamma-1) .

If gamma of a gas is equal to 1.66 then what is the number of atoms in a molecule of the gas?

The ratio between the specific heats of an ideal gas is y. show that the number of freedom of the gas molecules is n=2/(y-1)

From the relation C_p-C_v=R show that the ratio of two specific heats (gamma) of an ideal gas is given by gamma=1+2/f where f is the degrees of freedom of the molecule.

If gamma be the ratio of specific heats at cosntant pressure & constant volume, then show that the degree of freedom Is n = 2/(gamma-1)

An ideal gas undergoes a quasi-static, reversible process in which its molar heat capacity C remains constant. If during this process the relation of pressure p and volume V is given by pV^(n) = constant, then n is given by (Here C_(p) and C_(v) are molar specific heat at constant pressure and constant volume, respectively)

10 mol of an ideal gas is taken through an isothermal process in which the volume is compressed from 40 L to 30 L. If the temperature and the pressure of the gas are 0^(@)C and 1 atm respectively. Find the work done in the process. Given: R = 8.31 J cdot mol^(-1) cdot K^(-1) .