In an isothermal expansion of a gaseous sample the correct relation is (consider `w`(work) with sign according to new `IUPAC` convention)
[The reversible and irreversible processes are carried out between same initial and final states]

Statement -1: The magnitude of the work involved in an isothermal expansion is greater than that involved in an adiabatic expansion. Statement -2: P-v curve (P on y -axis and V on X-axis) decrease more rapidly for reversible adiabatic expansion compared to reversible isothermal expansion starting from same initial state.

Staetement -1: The magniyude of the work involed in an isothermal expansion is greater than that involved in an adiabatic expansion. Statement -2: P-v cure (pon y -axas and V on X-axas) decrease more repidly for reversible asiabatic expansion compared to reversible isothermal expansion starting from same initial state.

A gaseous sample is generally allowed to do only expansion // compression type work against its surroundings The work done in case of an irreversible expansion ( in the intermediate stages of expansion // compression the states of gases are not defined). The work done can be calculated using dw= -P_(ext)dV while in case of reversible process the work done can be calculated using dw= -PdV where P is pressure of gas at some intermediate stages. Like for an isothermal reversible process. Since P=(nRT)/(V) , so w=intdW= - underset(v_(i))overset(v_(f))int(nRT)/(V).dV= -nRT ln(V_(f)/(V_(i))) Since dw= PdV so magnitude of work done can also be calculated by calculating the area under the PV curve of the reversible process in PV diagram. If four identical samples of an ideal gas initially at similar state (P_(0),V_(0),T_(0)) are allowed to expand to double their volumes by four different process. I: by isothermal irreversible process II: by reversible process having equation P^(2)V= constant III. by reversible adiabatic process IV. by irreversible adiabatic expansion against constant external pressure. Then, in the graph shown in the final state is represented by four different points then, the correct match can be

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 :

There are two statement of same gas initially under similar initial state. Gases of both the samples are expanded. I^(st) sample using reversible isothermal process and II^(nd) sample using reversible adiabatic process till final pressure of both the samples becomes half of initial pressure. Then:

There are two statement of same gas initially under similar initial state. Gases of both the samples are expanded. I s t sample using reversible isothermal process and I I n d sample using reversible adiabatic process till final pressure of both the samples becomes half of initial pressure. Then:

For an ideal gas, the work of reversible expansion under isothermal condition can be calculated by using expression = -nRT ln.(V_(f))/(V_(i)) . A sample containing 1.0 mol of an ideal gas is expanded isothermally and reversible to ten times of its original volume, in two separate experiments. The expansion is carried out at 300 K and at 600 K respectively. Choose the correct option

(a) A certain mass of gas initially at (1L, 5 atm, 300 K) is expanded reversible and isothermally to final volume of 5L , calculate the work done by the gas and heat supplied in this process to the gas. (b) Now, if the gas is released to initial position by compressing it using an external constant pressure of 5 atm. Find work done on the gas in this process and heat rejected by gas (c ) In the above two processes, what is the net gained by surroundings ? [Note: From above question see that surrounding has done extra work on the system but system has returned that work in the form of heat to surrounding and work is considered on organized form of energy while heat as an unorganised form hence in the above process, there must be net increment in randomness of universe which be called Entropy, soon]