`H_(2(g))` reacts with `I_(2(g))` to give `HI_((g))`. Write the rate equation and predict order of the reaction with respect to `H_(2)` and `I_(2)`.

Which one of the following equations is correct for the reaction N_(2)(g) + 3H_(2)(g) to 2NH_(3)(g) ?

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 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

Equilibrium constant K_c for the reaction H_2(g)+I_2(g) leftrightarrow HI_((g)) is 50. What is the value of K_c for the reaction 1/2 H_2(g)+1/2 I_2(g) leftrightarrow HI and 2HI (g) leftrightarrow H_2(g)+I_2(g) ?

At 700K equilibrium constant for the reaction : H_(2)(g) +I_(2)(g)hArr2HI(g) is 54.8 . If 0.5mol^(-1) of HI(g) is present at equilibrium at 700K . What are the concentration of H_(2)(g) and I_(2)(g) assuming that we initially started with HI(g) and allowed it to reach equilibrium at 700K ?

In the reaction H_(2)(g) + Cl_(2) (g) rarr 2HCI(g) , relation between K_(p) and K_(c) is

For the reaction 2NO(g)+O_(2)(g)to2NO_(2(g)) volume is suddenly reduced to half its value by increasing the pressure on it. If the reaction is of first order with respect to O_(2) and second order with respect to NO, the rate of reaction will