For the reaction, `A (g) + 2B(g) rarr 2C(g) + 3D(g)` the change of enthalpy at `27^@C` is 19 kcal. The value of `Delta E` is:

X(g) + 2Y(g) rarr 2Z(g) + 3A(g) The change in enthalpy at 27^(@)C is 79.5 kJ. The value of Delta U is

For the reaction, A(s) + 3B(g) rarr 4C(g) + d(l) Delta H and Delta U are related as :

The value of enthalpy change ( DeltaH ) for the reaction C_2H_5OH(l) + 3O_2(g) to 2CO_2(g) +3H_2O(l) at 27^@C is -1366.5 kJ mol^(-1) . The value of internal energy change for the above reaction at this temperature will be

For the reaction 2A (g) + B(g) to C (g) Delta U^(@) = 20 kcal/mole, Delta S^(@) = 100 cal/kmole at 300 K. Hence Delta G^(@) in kcal is __________ [R = 2 cal mol^(-1) K^(-1)]

3 moles of A and 4 moles of B are mixed together and allowed to come into equilibrium according to the following reaction. 3A(g) + 4B(g) rarr 2C(g) + 3D(g) When equilibrium is reached, there is 1 mole of C. The equilibrium constant of the reaction is

For a gaseous reaction A(g) + 3 B(g) rightarrow 3C(g) + 3D(g) Delta E is 27 kcal at 37^(@)C . Assuming R = 2 cal K^(-1) mol^(-1) the value of Delta H for the above reaction will be

At 1000 K, the value of K_(p) for the reaction: A(g) + 2B(g)hArr3C(g) + D(g) is 0.05 atmosphere. The value of K_(c) in terms of R would be:

For a gaseous reaction, A(g)+3B(g)to3C(g)+3D(g),DeltaU is 17 kcal at 27^(@)C . Assuming R=2cal" "K^(-1)mol^(-1) , the value of DeltaH for the above reaction is:

For the reaction at 298 K A(g) + B(g) hArr C(g) + D(g) If DeltaH^(@) =29.8 Kcal and DeltaS^(@)=0.1 Kcal K^(-1) then calculate reaction constant (k)

For the formation of C(g) "at" 300 K. A(g) + 3B(g) rarr 2C(g) Calculate the magnitude of DeltaG^(@) (Kcal) if given data: {:(,A,B,C),(DeltaH_(f)^(@)("Kcal mol"^(-1)),0,0,-10),(DeltaS_(f)^(@) ("Cal K"^(-1) "mol"^(-1)), 40,30,45):}