In the system `A_((s)) hArr 2B_((g)) + 3C_((g))` . If the concentration of C at equilibrium is increased by a factor of 2. It will casuse the equilibrium concentration of B to change to:

For the Chemical reaction A_(2(g)) + B_(2(g)) hArr 2 AB(g) the amount of AB at equilibrium is affected by

The initial concentrations of A and B are same for A +2B harr 3C and when equilibrium concentrations of B and C are same then K_(c) is

In reversible reaction CaF_(2(g)) hArr Ca^(+2)""_(aq) + 2F_((aq)^(+))^(-) , the concentration of fluoride ions was made halved, then equilibrium concentration of Ca^(+2)

A(g) + 3(g) hArr 4C(g) Initial concentration of A is equal to that of B. The equilibrium concentration of A and C are equal. K_(c) is equal to .

The Kc for the reaction I_(2 (g)) hArr 2I_((g)) is 4 xx 10^(-3) . If the equilibrium concentration of atomic iodine is 4 xx 10^(-2) M . What is the concentration of molecular iodine ?

The equilibrium conatant for the reaction H_(2(g)) + I_(2(g)) hArr 2HI_((g)) is 2 at a certain temperature. The equilibrium concentrations of H_(2) and HI are 2 mole . lit^(-1) . What is the equilibrium concentration (in mole lit^(-1) ) of I_(2) ?

The equilibrium constant K_(c) for the SO_(2(g)) + NO_(2(g)) hArr SO_(3(g)) + NO_((g)) reaction is 16. if 1 mole of each of all the four gases is taken in ldm^(3) vessel, the equilibrium concentration of NO would be

AB_(2) dissociates as : AB_(2 (g)) hArr AB_((g)) + B_((g)) When the intial pressure of AB_(2) is 500 mm Hg , the total equilibrium pressure is 700 mm Hg . Calculate equilibrium constant for the reaction , assuming that the volume of the system remains unchanged .

At equilibrium AB_5 (g) leftrightarrow AB_3(g) +B_2(g) the concentrations of AB_5 and AB_3 are 0.2 and 0.1 mol L^-1 respectively. If K_c=0.5 mol L^-1 calculate the equilibrium concentration of B_2 .

In the equilibrium NH_(4) HS_(s) hArr NH_(3(g)) + H_(2) S_((g)) . the forward reaction can be favoured by