`A(g)hArr B(g)+C(g),K_C=10^(-8)`
`C(g)hArr D(g),K_C=10^(-5)`
1 mole of A(g) is taken in a closed container of volume 1 litre at temperature T. If concentration of D at equilibrium is `10^(-x)`, then , calculate value of x.

Consider the following equilibrium reaction at T K in a 1L flask. (I) A(g)iffB(g)+C(g), K_(C_(1))=3 (II) B(g)iff D(g)+C(g), K_(C_(2))=? If initially 2 moles of A(g) are taken and allowed attain equilibrium, concentration of C(g) was formed to be 3M. What is the value of K_(C ) of second reaction ?

2 mol of C(g) and 4 mole of D(g) are taken in a closed rigid container of 1 litre volume and allowed to attain equilibrium as : A(g)+2B(g)hArr C(g)+D(g),K_C=10^(-8) Calculate the equilibrium concentration of C(g).(If your answer in scientific notation is x xx10^(-y) then fill y).

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

For the reaction 2A(g)+B(g)hArr C(g)+D(g), K_c=10^(12) .if initially 4,2,6,2 moles of A,B,C,D respectively are taken in a 1 litre vessel, then the equilibrium concentration of A is :

The value of K for H_(2)(g)+CO_(2)(g)hArr H_(2)O(g)+CO(g) is 1.80 at 1000^(@)C . If 1.0 mole of each H_(2) and CO_(2) placed in 1 litre flask, the final equilibrium concentration of CO at 1000^(@)C will be

For the given equilibrium L_((g)) hArr M_((g)) The K_f =5xx10^(-4) mole /litre /seconds and k_b=3 xx 10^(-2) litre/mole /seconds the equilibrium concentration of M is

The value of K_(c) for the reaction : H_(2)(g)+I_(2)(g)hArr 2HI(g) is 45.9 at 773 K. If one mole of H_(2) , two mole of I_(2) and three moles of HI are taken in a 1.0 L flask, the concentrations of HI at equilibrium at 773 K.

For a reaction A_((g)) + B_((g))hArrC_((g)) + D_((g)) the intial concentration of A and B are equals but the equilibrium constant of C is twice that of equilibrium concentration of A. Then K is

For the equilibrium H_(2)(g)+CO_(2)(g)hArr hArr H_(2)O(g)+CO(g), K_(c)=16 at 1000 K. If 1.0 mole of CO_(2) and 1.0 mole of H_(2) are taken in a l L flask, the final equilibrium concentration of CO at 1000 K will be