In the P - V diagram, I is the initial state and F is the final state. The gas goes from I to F by
(i) IAF, (ii) IBF and (iii) ICF.

The heat absorbed by the gas is

When a thermodynamic system is taken from an initial state I to a final state F along the path IAF, as shown in Fig. the heat energy absorbed by the system is Q = 55 J and work done by the system is W = 25 J . If the same system is taken along the path IBF, the value of Q = 35 J . (a) If W = - 15 J for the curved path FI, how much heat energy is lost by the system along this path ? (b) If U_(1) = 10 J , what is U_(F) ? (d) If U_(B) = 20 J , what is Q for the process BF and IB ?

One mole of an ideal gas is taken from state A to state B by three different processes (a) ACB , (b) ADB and (c ) AEB as shown in the P - V diagram. The heat absorbed by the gas is

An ideal gas of mass m in a state A goes to another state B via three different processes as shown in Fig. If Q_(1), Q_(2) and Q_(3) denote the heat absorbed by the gas along the three paths, then

Six grams of hydrogen gas at a temperature of 273 K isothoermally expanded to five times its initial volume and then isochorically heated so that the pressure in the final state becomes equal to that in the initial state. Find the total amount of heat absorbed by the gas during the entire process.

An ideal gas goes from State A to state B via three different process as indicate in the P-V diagram. If Q_(2), Q_(3) indicates the heat absorbed by the gas along the three processes and DeltaU_(1), DeltaU_(2), DeltaU_(3) indicates the change in internal energy along the three processes respectively, then

An ideal gas undergoes a four step cycle as shown in the P-V diagram below. During this cycle heat is absorbed by the gas in

Figure shows the p-V diagram of an ideal gas undergoing a change of state from A to B. Four different parts I, II, III and IV as shown in the figure may lead to the same change of state. ltBrgt

A thermodynamic system goes from states (i) P_(1) V to 2P_(1) , V (ii) P , V to P , 2 V . Then work done in the two cases is

An ideal gas goes from the state i to the state int as shown in .the work done by the gas during the process