One mole of an ideal gas at an initial temperature to is taken through a process in which its pressure P varies with absolute temperature T is `P=(2P_(0))/((1+T//T_(0))`. Find its initial pressure and volume and find its temperature and volume when its pressure is half of the initial value.

An ideal gas (C_p//C_V = gamma) is taken through a process in which the pressure and the volume vary as P=aV^b .Find the value of b for which the specific heat capacity in the process is zero.

A one model of ideal gas goes through a process in which pressure P varies with volume V as p=3 - g ((V)/(V_0))^2 , where V_0 is a constant. The maximum attainable temperature by the ideal gas during this process is ( All quantities are SI units and R is gas constant)

One mole of oxygen gas in made to undergo a process in which its molar heat capacity C depends on its absolute temperature T as C = alpha T (where alpha is a positive constant). Work done by it when heated form an initial temperature T_0 to a final temperature 2T_0 , will be (3 alpha T_0 - x R)(T_0)/(2) then find x = ?

A one mole of ideal gas goes through a process in which pressure p varies with volume V as p =3-g((V)/(V_(0)))^(2) , where, V_(0) is a constant. The maximum attainable temperature by the ideal gas during this process is (all quantities are is SI units and Ris gas constant)

One mole of an ideal gas at an initial temperature of TK does 6R joules of work adiabatically. If the ratio of specific hats of this gas a constant pressure and at constant volume is 5/3, the final temperature (T_f) of gas will be :

A gas of temperature T_0 is enclosed in a container whose walls are (initially) at temperature T. Now, the gas exerts a higher pressure on the walls of the container when

One mole of an ideal monoatomic gas at 27^(@)C is subjected to a reversible isoentropic compression until final temperature reaches 327^(@)C . If the initial pressure was 1.0 atm then find the value of ln P_(2) :