The equilibrium constant `K_(c)` for the reaction `P_(4)(g) hArr 2P_(2)(g)` is `1.4` at `400^(@)C`. Suppose that 3 moles of `P_(4)(g)` and 2 moles of `P_(2)(g)` are mixed in 2 litre container at `400^(@)C`. What is the value of reaction quotient `(Q)` ?

The equilibrium constant K_(p) for the reaction H_(2)(g)+I_(2)(g) hArr 2HI(g) changes if:

K_(p)//K_(c) for the reaction CO(g)+1/2 O_(2)(g) hArr CO_(2)(g) is

The relation between K_(P) and K_(C) for the reaction A(g)+B(g) hArr C(g)+2D(g) is -

The equilibrium constant K_(p) , for the reaction N_(2)(g)+3H_(2)(g) hArr 2NH_(3)(g) is 1.6xx10^(-4) at 400^(@)C . What will be the equilibrium constant at 500^(@)C if the heat of reaction in this temperature range is -25.14 kcal?

The relation K_(p) " and " K_(c) for the reaction: 2NO (g) + CI_(2) (g) hArr 2NOCI(g) " is":

Calculate K_p from K_c : The equilibrium constant, K_c , for the reaction N_2O_4(g) hArr 2NO_2(g) is 3.64xx10^-3 at 25^@C . What is the value of K_p at this temperature?

At a certain temperature , the equilibrium constant (K_(c)) is 4//9 for the reaction : CO(g)+H_(2)O(g) hArr CO_(2)(g)+H_(2)(g) If we take 10 mole of each of the four gases in a one - litre container, what would be the equilibrium mole percent of H_(2)(g) ?

At 700 K , the equilibrium constant K_(p) for the reaction 2SO_(3)(g)hArr2SO_(2)(g)+O_(2)(g) is 1.80xx10^(-3) kPa . What is the numerical value of K_(c ) in moles per litre for this reaction at the same temperature?