If one third HI decomposes at a particular temperature: `K_c` for `2HI hArr H_2+ I_2` is :

Two moles of NH_3 are introduced into one litre flask in which it dissociates at high temperature as 2NH_3(g) hArr N_2(g) + 3H_2(g) Find the value of K_C .

The differential rate law for the reaction H_2 + I_2 rarr 2HI is

Two reactions, (i) A to Products, (ii) B to Products, follow first order kinetics. The rate of reaction (i) is doubled when the temperature is raised from 300K to 310K. The half-life for this reaction at 310 K is 10 min. At, the same temperature, B decomposes twice as the same temperature, B decomposes twice as reaction (ii) is half that of reaction (i), calculate the rate constant of the reaction (ii), at 300K.

Which is not decomposed by dil. H_2SO_4

the equiliberium constant K for the reaction 2HI (g) ⇌ H_2 (g) + I_2 (g) at room temperature 300 K is 2.85 and at 698 K is 1.84 xx 10^(-2) . Hence the reason that HI existsas a stable compound at room temperature is because :

K_p/K_c for the reaction: CO(g)+1/2O_2(g) hArr CO_2(g) is :

At 25^oc the equilibrium constant K_1 and K_2 of two reaction are : 2NH_3 hArr N_2 +3H_2 : 1/2N_2 +3/2H_2 hArr NH_3 the relation between two equilibrium constant is :