Molar heat capacity of a gas at constant volume.

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 .

A defintie amount of diatomic ideal gas undergoes reversible adiabatic expansion from 10 L, 127^(@)C to 'V'L,-73^(@)C. The molar heat capacity of gas at constant volume is : [Given : R=8.3JK^(-1),ln 2 =0.7.ln 30=3.4]

Molar heat capacity of a gas at constant pressure .

Two identical thermally insulated vessels interconnected by a tube with a valve contain one mole of the same ideal gas each. The gas temperature in one vessel is equal to T_1 and in the other, T_2 . The molar heat capacity of the gas of constant volume equals C_v . the valve having been opened, the gas comes to a new equilibrium state. Find the entropy increment Delta S of the gas. Demonstrate that Delta S gt 0 .

C_(V)andC_(P) denote the molar specific heat capacities of a gas at constant volume and constant pressure, respectively. Then

Molar heat capacity of an ideal gas at constant volume is given by C_(V)=2xx10^(-2)J (in Joule). If 3.5 mole of hits ideal gas are heated at constant volume from 300K to 400K the change in internal energy will be