1 mole of a real gas changes it state from state-A(2bar, 3L, 100 K) to state -B (2bar, 5L, 200 K) at constant pressure and finally to state-C (3bar, 10 L, 300 K). If `DeltaU_(BC) = 110 J` and `C_(Pm)` of gas `=3R = 3 xx 8.3 JK^(-1)mol^(-1)` then thoose the correct option(s) :

1.5 moles of a real gas changes its state from state A (3bar, 2 L, 200 K) to state b (3 bar, 5 L, 300 k) through isobaric process. It is then taken to state C (4bar, 10 L 400 K ) such that DeltaU_(BC)=127 Joules. Calculate value of DeltaU_(AC) in joules. [Given : C _(p,m) of gas = 4 R and R=8.3JK^(-1)mol^(-1)]

A system containing real gas changes it's state from state -1 to state - 2 . State -1 ( 2atm, 3L,300K) State-2 (5 atm, 4L,500K) If change in internal energy = 30 L atm then calculate change in enthalpy.

One mole of a non-ideal gas undergoes a change of state from (2,0 atm, 3.0 L, 100 K) to (4.0 atm, 5.0 L, 250 K) with a change in internal energy, DeltaU=30.0 Latm. The change on enthalpy of process in (L - atm) is

A real gas is subjective to an adiabatic process form (2"bar",40L,300K) to (4"bar",30L,300K) against a constant pressure of 4 bar. The enthalpy change for the process is (1"bar"-litre=100J):

One mole of non - ideal gas undergoes a change of state (1.0 atm, 3.0L, 200 K ) to (4.0 atm, 5.0L,250 K) with a change in internal energy (DeltaU)=40 L-atm . The change in enthalpy of the process in L-atm ,

2 mole of a gas at 1 bar and 300 K are compressed at constant temperature by use of a constant pressure of 5 bar. How much work is done on the gas ?