An ideal gas can be expanded form an initial state to a certain volume through two different processes `PV^(2) =` constant and (ii) `P = KV^(2)` where `K` is a positive constant. Then

An ideal gas can be taken form initial state 1 to final state 2 by two different process. Let DeltaQ and W represent the heat given and work done by the system. Then which quantities is/are same in both process (where DeltaU = internal energy of gas)

An ideal gas expands in such a way that PV^2 = constant throughout the process.

An ideal gas expands according to the law PV^(3//2) =constant We conclude that

0.5 litre of an ideal gas at a pressure of 20 atm expands to a final volume of 0.5 m ^(3). The process obeys the equation PV = a constant, (i) Find the value of this constant (ii) What is the final pressure ? And (iii) Find, the work done by the gas,

An ideal gas expands in such a manner that its pressure and volume can be related by equation PV^(2) = constant. During this process, the gas is

In the process pV^2= constant, if temperature of gas is increased, then

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

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

P-V graph for an ideal gas undergoing polytropic process PV^(m) = constant is shown here. Find the value of m.

The internal energy of a certain substance is given by the following equation : U=3 PV+84 where U is given in kJ/kg, P is in kPa, and V is in m^3//kg A system composed of 3 kg of this substance expands from an initial pressure of 400 kPa and a volume of A 0.2 m^3 to a final pressure 100 kPa in a process in which pressure and volume are related by PV^2 =constant. In another process the same system expands according to the same pressure-volume relationship as in above question, but from the same initial state of the final state as in above question, but the heat transfer in this case is +30 kJ.Then the work transfer for this process is :