1 mole of A is allowed to decompose in a 1-litre container. 0.4 mole of B was produced at equilibrium. The equilibrium constant `K_(c)` for the equilibrium
`A(g)hArr2B(g)+C(g)`, is

The figure shows the change in concentration of species A and B as a function of time. The equilibrium constant K_(c) for the reaction A(g)hArr2B(g) is :

1 mole of 'A' 1.5 mole of 'B' and 2 mole of 'C' are taken in a vessel of volume one litre. At equilibrium concentration of C is 0.5 mole /L .Equilibrium constant for the reaction , A_((g))+B_((g) hArr C_((g)) is

In the decomposition reaction AB_(5)(g)hArrAB_(3)(g)+B_(2)(g) , at equilibrium in a 10 litre closed vessel at 227^(@)C , 2 moles of AB_(3) , 5 moles of B_(2) and 4 moles of AB_(5) , are present. The equilibrium contstant K_(c) for the formation of AB_(5)(g) is

In an experiment , 2 moles of HI are taken into an evacuated 10.0 litre container at 720 K. The equilibrium constant equals to 0.0156for the gaseous reaction, 2 HI (g) hArr H_(2) (g) + I_(2)(g). find equilibrium concentration of HI (g) , H_(2) (g) , I_(2)(g).

In an experiment 5 moles of HI were enclosed in a 5 litre container . At 717 K equilibrium constant for the gaseous reaction , 2HI (g) hArr H_2(g) +I_2(g) is 0.025 . Calculate the equilibrium concentration of HI H_2 and I_2 . What is the fraction of HI that decomposes ?

In 500 ml capacity vessel CO and Cl_(2) are mixed to form COCl_(2) . At equilibrium, it contains 0.2 moles of COCl_(2) and 0.1 mole of each of CO and Cl_(2) , The equilibrium constant K_(C) for the reaction CO(g)+Cl(g)hArrCOCl_(2)(g) is

4.5 moles each of hydrogen and iodine heated in a sealed 10 litrevesel. At equilibrium, 3 moles of HI was foun. The equilibrium constant for H_(2)(g) + I_(2) (g)hArr2HI(g) is

2 mole of X and 1 mole of Y are allowed to react in a 2 litre container.when equilibrium is reached, the following reaction occurs 2X(g)+Y(g) hArr Z(g) at 300 K. If the moles of Z at equilibrium is 0.5 then what is equilibrium constant K_C ?

5 litre vessel contains 2 moles of each of gases A and B at equilibrium. If 1 mole each of A and B are removed. Calculate K_(C) for the reaction A(g) iffB(g)