At a given temperature, Ke is 4 for the reaction `H_(2(g)) + CO_(2(g)) hArr H_(2)O_((g)) + CO_((g))`. Initially 0.6 moles each of `H_(2) and CO_(2)` are taken in 1lit flask. The equilibrium concentration of `H_(2) O_((g))` is

The equilibrium constant for the reaction , H_(2) (g) + CO_(2) (g) hArr H_(2) O (g) + CO (g) is 16 at 1000^(@) C . If 1.0 mole of H_(2) and 1.0 mole of CO_(2) are placed in one litre flask , the final equilibrium concentration of CO at 1000^(@) C is

in manufacture of NO, the reaction N_(2(g)) + O_(2(g)) hArr 2NO_((g)). Delta H + ve is favourable if :

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 enthalpy of the reaction H_(2(g)) + O_(2(g)) rarr H_2O_((g)) is DeltaH_1 and that of H_(2(g)) + O_(2(g)) rarr H_(2)O_((l)) is Delta H_2 . Then

For the equilibrium reaction, 3Fe_((s)) + 4H_(2) O_((g)) hArr Fe_(3)O_(4(s)) + 4 H_(2(g)) the relation between K_(p) and K_(c) is

The equilibrium constant for the reaction CO_((g)) + H_(2) O_((g)) hArr CO_(2(g)) + H_(2(g)) is 5. How many moles of CO_(2) must be added to I lit container already containing 3 moles of each of CO and H_(2) O to make 2M equilibrium concentration of CO ?

The reaction H_(2(g))+I_(2(g)) harr 2HI_((g)) is carried out in a 1 litre flask. If the same reaction is earned out in a 2 litre flask at the same temperature, the equilibrium constant will be

The enthalpy of the reaction H _(2 (g)) + 1/2 O _(2(g)) to H _(2) O _((g)) is Delta H _(1) and that of H _(2(g)) + 1/2 O _(2(g)) to H _(2) O _((l)) is Delta H _(2). Then