Calculate the maximum work done (in multiple of `10^(3)`) in expanding 16g of oxygen at 300K and occupying a volume of `5 dm^(3)` isothermally, until the voume becomes `25 dm^(3)` (Give you anwer as nearest integer)

0.14kg of nitrogen at 300K is expanded isothermally and reversibly until its volume becomes doubled. Calculate the work done by the gas.

Calculate the work done by the system in an irreversible (sing step) adiabatic expansion of 2 mole of a polyatomic gas (gamma= 4//3) from 300K and pressure 10atm to 1 atm: (in KJ) (Give your answer after multiplying with 2.08).

Calculate the total pressure in a mixture of 3.5 g of dinitrogen 3.0 g of dihydrogen and 8.0 g dioxygen confined in vessel of 5 dm^3 at 27^@C (R=0.083 bar dm^3K^-1 mol^-1)

Two moles of an ideal monoatomic get at 27^(@)C occupies a volume of V. If the gas is expanded adiabatically to the volume 2V, then the work done by the gas will be (gamma=5//3)

At 400K, 5 moles of an ideal gas expands isothermally and reversibly from 10dm^3 to 20 dm^3 . Calculate the work done by the gas.

The number of correct statements among the following 1 The expansion work for a gas into vacuum is equal to zero. 2. 1 mole of a gas occupying 3 litre volume on expanding to 15 litre at constant pressure of 1 atm does expansion work 1.215kJ. 3. The maximum work done by the gas during reversible expansionof 16g O_(2) at 300K from 5dm^(3) to 25dm^(3) is 2.0074 kJ. 4. The DeltaS "for " s rarr l is almost negligible in comparison to DeltaS for l rarr g . 5. DeltaS= 2.303 nR "log" (V_(2))/(V_(1)) (at constant T) 6. Reversible isothermal work done = -2.303nRT "log"_(10) (V_(2))/(V_(1))