Show that the entropy of a perfect gas can be written as `S=C_(v) In p+C_(p) In V+S_(0)` where `S_(0)` is a constant.

One mole of an ideal gas goes through a process in which the entropy of the gas changes with temperature T as S = aT + C_V 1n T , where a is a positive constant. C_V is the molar heat capacity of this gas at constant volume. Find the volume dependence of the gas temperature in this process if T = T_0 at V = V_0 .

One mole of an ideal gas with heat capacity at constant pressure C_(P) undergoes the process T=T_(0)+alpha V where T_(0) and a are constants.If its volume increases from V_(1)toV_(2) the amount of heat transferred to the gas is C_(P)RT_(0)ln((V_(2))/(V_(1))) O alpha C_(P)((V_(2)-V_(1)))/(RT_(0))ln((V_(2))/(V_(1))) qquad alpha C_(P)(V_(2)-V_(1))+RT_(0)ln((V_(2))/(V_(1)))

One mole of an ideal gas with heat capacity at constant pressure C_(P) undergoes the process T=T_(0)+alpha V where T_(0) and a are constants.If its volume increases from V_(1)toV_(2) the amount of heat transferred to the gas is C_(P)RT_(0)ln((V_(2))/(V_(1))) alpha C_(P)((V_(2)-V_(1)))/(RT_(0))ln((V_(2))/(V_(1))) alpha C_(P)(V_(2)-V_(1))+RT_(0)ln((V_(2))/(V_(1)))

V = k((P)/(T))^(0.33) where k is constant. It is an,

One mole of an ideal gas undergoes a process P = P_(0) [1 + ((2 V_(0))/(V))^(2)]^(-1) , where P_(0) V_(0) are constants. Change in temperature of the gas when volume is changed from V = V_(0) to V = 2 V_(0) is:

The internal energy of a gas is given by U = 3 pV. It expands from V_(0) to 2V_(0) against a constant pressure p_(0) . What is the value of gamma(=C_(P)//C_(V)) for the given gas?

One mole of a diatomic gas undergoes a process P = P_(0)//[1 + (V//V_(0)^(3))] where P_(0) and V_(0) are constant. The translational kinetic energy of the gas when V = V_(0) is given by