For these reactions,
I `H_2(g)+I_2(g) iff 2HI(g)K_c`
` II 2HI(g) iff H_2(g)+I_2(g) :k_c`
`K_C` and `K_c^'` are related as

For a reaction, H_2(g)+I_2(g) iff 2HI(g) K_c=[HI(g)]^2/[H_2(g)[I_2(g)] Point out the correct statement.

For reaction H_(2)(g) +I_(2)(g) hArr 2HI (g) The value of K_(p) changes with

For the reaction H_(2)(g) + I_(2)(g)hArr2HI(g)K_(c) = 66.9 at 350^(@)C and K_(c) = 50.0 at 448^(@)C . The reaction has

In the reversible reaction, 2HI(g) hArr H_(2)(g)+I_(2)(g), K_(p) is

For the reaction A(g) iff B (g), K_(C)=10 B(g) iff C(g), K_(C)=2 C(g) iff D(g), K_(C)=0.01 Calculate K_(C) for the reaction D(g) iff A(g) .

The value of K_(c) for the reaction H_(2)(g)+I_(2)(g) hArr 2HI(g) is 64 at 773K . If one "mole" of H_(2) , one mole of I_(2) , and three moles of HI are taken in a 1 L flask, find the concentrations of I_(2) and HI at equilibrium at 773 K .

Equilibrium constant for the reaction: H_(2)(g) +I_(2) (g) hArr 2HI(g) is K_(c) = 50 at 25^(@)C The standard Gibbs free enegry change for the reaction will be: