For the case of an ideal gas find the equation of the process (in the variables `T, V`) in which the molar heat capacity varies as :
(a) `C = C_V + alpha T` ,
(b) `C = C_V + beta V `,
( c) `C = C_v + ap` ,
where `alpha, beta` and `a` are constants.

For a Van der Walls gas find : (a) the equation of the adiabatic curve in the variables T, V , the difference of the molar heat capacities C_p - C_v as a function of T and V .

For an ideal gas the molar heat capacity varies as C=C_V+3aT^2 . Find the equation of the process in the variables (T,V) where a is a constant.

For an ideal gas the equation of a process for which the heat capacity of the gas varies with temperatue as C=(alpha//T(alpha) is a constant) is given by

Find the relatio between volume and temperature of a gas in a process, in which the molar heat capacity C varies with temperature T as C=C_(V)+alphaT . [ alpha is a constant] .

Molar heat capacity of an ideal gas varies as C = C_(v) +alphaT,C=C_(v)+betaV and C = C_(v) + ap , where alpha,beta and a are constant. For an ideal gas in terms of the variables T and V .

For an ideal gas C_(p) and C_(v) are related as

An ideal gas is taken through a process in which pressure and volume vary as P = kV^(2) . Show that the molar heat capacity of the gas for the process is given by C = C_(v) +(R )/(3) .

An ideal gas has a molar heat capacity C_v at constant volume. Find the molar heat capacity of this gas as a function of its volume V , if the gas undergoes the following process : (a) T = T_0 e^(alpha v) , (b) p = p_0 e^(alpha v) , where T_0, p_0 , and alpha are constants.

The molar heat capacity of an ideal gas in a process varies as C=C_(V)+alphaT^(2) (where C_(V) is mola heat capacity at constant volume and alpha is a constant). Then the equation of the process is

For an ideal monoatomic gas, molar heat capacity at constant volume (C_(v)) is