In the isothermal reversible compression of `52.0m` mol of a perfect gas at `260 K`, the volume of the gas is reduced to one`-`third of its initial value. Calculate `w` of this provess `y`.

The pressure of a certain volume of a gas is reduced to half of its initial pressure at contant temperature. Calculate its new volume.

Calculate work done during isothermal reversible process when 5 mol ideal gas is expanded so that its volume is doubled at 400K .

Calculate q,w , and DeltaU for the isothermal reversible expansion of one mole of an ideal gas from an initial pressure of 2.0 bar to a final pressure of 0.2 bar at a constant temperature of 273K .

Calculate q, W, DeltaU and DeltaH for the isothermal reversible expansion of one mole of an ideal gas from an initial pressure of 1.0 bar to a final pressure of 0.1 bar at a constant temperature of 273K.

Calculate q, W, DeltaU and DeltaH for the isothermal reversible expansion of one mole of an ideal gas from an initial pressure of 1.0bar to a final pressure of 0.1bar at a constant temperature of 273K .

If one mole of an ideal gas at (P_1, V_1) is allowed to expand reversibly and isothermally (A to B) its pressure is reduced to one-half of the original pressure (see figure). This is followed by a constant volume cooling till its pressure is reduced to one-fourth of the initial value (BrarrC) . Then it is restored to its initial state by a reversible adiabatic compression (C to A). The net workdone by the gas is equal to :

Calculate q,w,DeltaU , and DeltaH for this isothermal reversible expansion of 1mole of an ideal gas from an initial pressure of 10.0 bar to final pressure of 100 bar at a constant pressure of 273K .

The volume of a given mass of a gas is reduced to 1/4 th of its initial value of at constant temperature. Calculate the percentage change in the pressure of the gas.