For the reaction `I_(2)(g) hArr 2I(g)`, `K_(c) = 37.6 xx 10^(-6)` at 1000K . If 1.0 mole of `I_(2)` is introduced into a 1.0 litre flask at 1000K, at equilibrium

If 1.0 "mole" of I_(2) is introduced in a 1.0 litre flask at 1000 K(K_(c)=10^(-6)) , which one is correct?

K_c for the reaction : 2H_2S(g) hArr 2H_2(g) + S_2(g) is 1xx10^(-6) at 100 K. What is the dissociation of H_2S is 1 mole of H_2S is introduced in a 1.1 L of flask at 1000 K?

The value of K for H_(2)(g)+CO_(2)(g)hArr H_(2)O(g)+CO(g) is 1.80 at 1000^(@)C . If 1.0 mole of each H_(2) and CO_(2) placed in 1 litre flask, the final equilibrium concentration of CO at 1000^(@)C will be

For the equilibrium H_(2)(g)+CO_(2)(g)hArr hArr H_(2)O(g)+CO(g), K_(c)=16 at 1000 K. If 1.0 mole of CO_(2) and 1.0 mole of H_(2) are taken in a l L flask, the final equilibrium concentration of CO at 1000 K will be

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

For the reaction 2NO_(2)(g) hArr 2NO(g)+O_(2)(g) K_(c)=1.8xx10^(-6) at 184^(@)C, R=0.00831 kJ // ( mol.K) when K_(p) and K_(c) are compared at 184^(@)C , it is found