At `540 K, 0.10 mol` of `PCl_(5)` is heated in a `8L` flask. The pressure of equilibrium mixture is found to be `1.0 atm`. Calculate `K_(p)` and `K_(c )` for the reaction.

For the reaction, 2NO(g)+Cl_(2)(g)hArr 2NOCl(g) a reaction mixture containing NO(g) and Cl_(2)(g) at partial pressure of 0.373 atm and 0.310 atm at 300 K respectively, is taken. The total pressure of the system at equilibrium was found to be 0.544 atm at 300 K. The value of K_(C) for the reaction, 2NOCl(g)hArr 2NO(g)+Cl_(2)(g) at 300 K would be

5 moles of PCl_(5) are heated in a closed vessel of 5 litre capacity. At equilibrium 40% of PCl_(5) is found to be dissociated. What is the value of K_(c) ?

Pure PCl_(5) is introduced into an evacuated chamber and to equilibrium at 247^(@)C and 2.0 atm .The equilibrium gases mixture contains 40% chlorine by volume . Calculate K_(p) at 247^(@)C for the reaction PCl_(5)(g)hArrPCl_(3)(g)+Cl_(2)(g)

Initially, 0.8 mole of PCl_(5) and 0.2 mol of PCl_(3 are mixed in one litre vessel. At equilibrium, 0.4 mol of PCl_(3) is present. The value of K_(c ) for the reaction PCl_(5)(g) hArr PCl_(3)(g)+Cl_(2)(g) would be

2.0 mole of PCl_(5) were nttoducedd in a vessel of 5.0 L capacity of a particular temperature At equilibrium, PCl_(5) was found to be 35 % dissociated into PCl_(3)and Cl_(2) the value of K_(c) for the reaction PCl_(3)(g)+Cl_(2)(g)hArrPCl_(5)(g)

If K_(p) for a reaction is 0.1 at 27^(@)C the K_(c ) of the reaction will be

3.00 mol of PCl_(5) kept in 1L closed reaction vessel was allowed to attain equilibrium at 3.80 K . Calculate composition of the mixture at equilibrium K_(c) = 1.80

Two moles of PCl_(5) were heated to 327^(@)C in a closed two-litre vessel, and when equilibrium was achieved, PCl_(5) was found to be 40% dissociated into PCl_(3) and Cl_(2) . Calculate the equilibrium constant K_(p) and K_(c) for this reaction.

Two moles of PCl_(5) were heated to 327^(@)C in a closed two-litre vessel, and when equilibrium was achieved, PCl_(5) was found to be 40% dissociated into PCl_(3) and Cl_(2) . Calculate the equilibrium constant K_(p) and K_(c) for this reaction.

The energy change accompanying the equilibrium reaction A hArrB is -33.0kJ mol^(-1) . Calculate Equilibrium constant K_a for the reaction at 300 K