The molar specific heat of a gas as given from the kinetic theory is `(5)/(2) R`. If it is not specified whether it is `C_(p) or C_(upsilon)` one could conclude that the molecules of the gas

Molar specific heat at constant volume C_v for a monatomic gas is

If the molar specific heat of a gas at constant pressure is 7/2R , then the atomicity of gas is

The molar specific heat at constant volume of gas mixture is (13R)/(6) . The gas mixture consists of

The molar specific heat at constant pressure of an ideal gas is 7/2R . The gas is made up of molecules which are

Figure shows P versus V graph for various processes performed by an ideal gas. All the processes are polytropic following the process equation PV^(k) = constant. (i) Find the value of k for which the molar specific heat of the gas for the process is (C_(P)+C_(V))/(2) . Does any of the graph given in figure represent this process? (ii) Find the value of k for which the molar specific heat of the gas is C_(V) + C_(P) . Assume that gas is mono atomic. Draw approximately the P versus V graph for this process in the graph given above.

The ratio of specific heats of a gas is 1.4. if the value of C_(V) is 20.8 J/mol K, then the C_(P) is

The molar specific heats of an ideal gas at constant pressure and volume are denotes by C_(P) and C_(upsilon) respectively. If gamma = (C_(P))/(C_(upsilon)) and R is the universal gas constant, then C_(upsilon) is equal to

If gamma be the ratio of specific heats (C_(p) & C_(v)) for a perfect gas. Find the number of degrees of freedom of a molecules of the gas?

The ratio of the specific heats (C_(P))/(C_(upsilon)) = gamma in terms of degrees of freedom is given by