A gaseous system changes from state `A(P_(1),V_(1),T_(1))` to `B(P_(2),V_(2),T_(2))`, `B` to `C(P_(3),V_(3),T_(3))` and finally from `C` to `A`. The whole process may be called

A gaseous system changes from state A (P_(1), V_(1),T_(1)) to B (P_(2), V_(2),T_(2)) to C(P_(3), V_(3),T_(3)) and finally from C to A . The whole process may be called :

A system Xundergoes following changes underset(P_(1)V_(1)T_(1))(X)to underset(P_(2)V_(2)T_(1))(W)tounderset(P_(3)V_(2)T_(2))(Z)tounderset(P_1V_(1)T_(1))X The overall process may be called as

A system changes from the state (P_(1),V_(1)) to (P_(2)V_(2)) as shwon in the diagram. The workdone by the system is

A system changes from the state (P_(1), V_(1)) to (P_(2) , V_(2)) as shown in the figure below. What is the work done by the system –

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

For an ideal gas, an illustration of the different paths, A (B + C) and (D + E) from an intial state P_(1), V_(1), T_(1) to a final state P_(2), V_(2), T_(1) as shown in the given figure. Path (A) represents a reversible isothernal expanison from P_(1)V_(1) to P_(2)V_(2) . Path (B + C) represents a reversible adiabatic expansion (B) from P_(1), V_(1), T_(1) to P_(3), V_(2), T_(2) followed by reversible heating the gas at constant volume (C) from P_(3), V_(2), T_(2) to P_(2), V_(2) T_(1) to P_(1) , V_(2), T_(3) followed by reversible cooling at a constant volume V_(2) (E) from P_(1), V_(2), T_(3) to P_(2), V_(2), T_(1) What is Delta S for path (D + E) ?

A gas with (c_(p))/(c_(V))=gamma goes from an intial state (p_(1), V_(1), T_(1)) to a final state (p_(2), V_(2), T_(2)) through an adiabatic process. The work done by the gas is

An ideal gas follows a process described by PV^(2)=C from (P_(1), V_(1),T_(1)) " to " (P_(2), V_(2), T_(2)) (C is a constant). Then

One mole of hydrogen, assumed to be ideal, is adiabatically expanded from its initial state (P_(1), V_(1), T_(1)) to the final state (P_(2), V_(2), T_(2)) . The decrease in the internal energy of the gas during this process will be given by