Temperature of an ideal gas is 300 K. The change in temperature of the gas when its volume changes from V to 2V in the process p = aV (Here, a is a positive constant) is

One mole. of an ideal gas undergoes a process P=(P_(0))/(1+(V_(0) / V)^(2)) . Here P_(0) and V_(0) are constants. The change in temperature of the gas when volume is changed from V=V_(0) to V=2 V_(0) is (x P_(0) V_(0))/(10 R) . Find x . (Here R= Uniyersal gas 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 .

For a sample of n mole of a perfect gas at constant temperature T (K) when its volume is changed from V_1 to V_2 the entropy change is given by

One mole of ideal gas gose through process P=(2V^(2))/((1+V^(2))) then change in temperature of the gas when volume changes from V=1m^(3) to 2m^(3) is :

The pressure (P) and absolute temperature (T) of an ideal gas are related to each other as Pprop(1)/(T^(2)) . If temperature of gas is 300 K and its volume changes from V to 8 V, then find the final temperature of gas.

If the ratio of specific heat of a gas of constant pressure to that at constant volume is gamma , the change in internal energy of the mass of gas, when the volume changes from V to 2V at constant pressure p is

If the ratio of specific heat of a gas at constant pressure to that at constant volume is gamma , the change in internal energy of a mass of gas, when the volume changes from V to 2V at constant pressure P, is