Figure shows the variations of the internal energy `U` With density `rho` one mole an ideal monatomic gas for thermodynamic cycle `ABCA` . Here process `AB` is a part of rectangular hyperbola,-

The figure shows the P-V plot of an ideal gas taken through a cycle ABCDA. The part ABC is a semi-circle and CDA is half of an ellipse. Then,

A weightless piston divides a thermally insulated cylinder into two parts of volumes V and 3V. 2 moles of an ideal gas at pressure P = 2 atmosphere are confined to the part with volume V =1 litre. The remainder of the cylinder is evacuated. The piston is now released and the gas expands to fill the entire space of the cylinder. The piston is then pressed back to the initial position. Find the increase of internal energy in the process and final temperature of the gas. The ratio of the specific heats of the gas, gamma =1.5 .

An ideal monoatomic gas occupies volume 10^(-3)m^(3) at temperature 3K and pressure 10^(3) Pa. The internal energy of the gas is taken to be zero at this point. It undergoes the following cycle: The temperature is raised to 300K at constant volume, the gas is then expanded adiabatically till the temperature is 3K , followed by isothermal compression to the original volume . Plot the process on a PV diagram. Calculate (i) The work done and the heat transferred in each process and the internal energy at the end of each process, (ii) The thermal efficiency of the cycle.

Figure shows a process ABCA performed on an ideal gas. Find the net heat given to the system during the process.

Two moles of an ideal monoatomic gas is taken through a cycle ABCA as shown in the P-T diagram. During the process AB , pressure and temperature of the gas very such that PT=Constant . It T_1=300K , calculate (a) the work done on the gas in the process AB and (b) the heat absorbed or released by the gas in each of the processes. Give answer in terms of the gas constant R.

One mole of an ideal monoatomic gas undergoes a cyclic process as shown in figure . Temperature at point 1 = 300K and process 2-3 is isothermal . Heat capacity of process 1rarr 2 is

In the given figure an ideal gas changes its state from A to state C by two paths ABC and AC . (i) Find the path along which work done is the least. (ii) The internal energy of gas at A is 10J and amount of heat supplied to change its state to C through the path AC is 200J . Calculate the internal energy at C . (iii) How much is the heat involved in the process ABC and ADC ?

Consider a P-V diagram in which the path followed by one mole of perfect gas in a cylindrical container is shown in figure. (a) Find the work done when the gas is taken from state 1 to state 2. (b) What is the ratio of temperature T_1/T_2 if V_2=2V_1 ? (c) Given the internal energy for one mole of gas at temperature T is 3/2RT , find the heat 2 supplied to the gas when it is taken from state 1 to 2, with V_2 = 2V_1

An ideal diatomic gas (gamma=7/5) undergoes a process in which its internal energy relates to the volume as U=alphasqrtV , where alpha is a constant. (a) Find the work performed by the gas to increase its internal energy by 100J. (b) Find the molar specific heat of the gas.