One mole of ideal gas goes through process`P = (2V^2)/(1+V^2)`. Then change in temperature of gas when volume changes from `V = 1m^2` to `2m^2` is :

If n moles of an ideal gas undergoes a thermodynamic process P=P_0[1+((2V_0)/V)^2]^(-1) , then change in temperature of the gas when volume is changed from V=V_0 to V=2V_0 is [Assume P_0 and V_0 are constants]

One mole of an ideal gas whose adiabatic exponent is gamma = 4/3 undergoes a process P = 200 + 1/V . Then change in internal energy of gas when volume changes from 2 m^2 to 4 m^3 is:

One mole of an ideal gas undergoes a process T = 300 + 2V. Then amount of work done by gas when volume increases from 2m^3 to 4m^3 :

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

Temperature of an ideal gas is 300 K . The final temperature of the gas when its volume changes from V " to " 2V in the process p=alphaV (here alpha 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. Change in temperature of the gas when volume is changed from V=V_(0) to V=2V_(0) is

One mole of an ideal gas undergoes a process p=(p_(0))/(1+((V)/(V_(0)))^(2)) where p_(0) and V_(0) are constants. Find temperature of the gaas when V=V_(0) .

One mole of an ideal monoatomic gas under goes a process V=aT^(2) . The temperature of the gas increases by 100 K . Which of the following is incorrect ?

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

One mole of an ideal gas undergoes a process P=P_(0)-alphaV^(2) where alpha and P_(0) are positive constant and V is the volume of one mole of gas Q. When temperature is maximum, volume is