One mole of an ideal gas undergoes a process in which `T = T_(0) + aV^(3)`, where `T_(0)` and `a` are positive constants and V is molar volume. The volume for which pressure with be minimum 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

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. The maximum attainable temperature is

find the minimum attainable pressure of an ideal gs in the process T = t_0 + prop V^2 , where T_(0)n and alpha are positive constants and (V) is the volume of one mole of gas.

Find the minimum attainable pressure of an ideal gas in the process T = T_(0) + alpha V^(2) , Where T_(0) and alpha are positive constant and V is the volume of one mole of gas. Draw the approximate T -V plot of this process.

An ideal gas with the adiabatic exponent gamma goes through a process p = p_0 - alpha V , where p_0 and alpha are positive constants, and V is the volume. At what volume will the gas entropy have the maximum value ?

Find the minimum attainable pressure of ideal gas in the process T = T_0 + alpha V^2 , where T_0 and alpha positive constants, and V is the volume of one mole of gas. Draw the approximate p vs V plot of this process.

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:

An ideal gas is made to undergo a process T = T_(0)e^(alpha V) where T_(0) and alpha are constants. Find the molar specific heat capacity of the gas in the process if its molar specific heat capacity at constant volume is C_(v) . Express your answer as a function of volume (V).