A possible mechanism for the conversion for ozone to oxygen in the upper atmosphere is
`O_(3)(g) hArr O_(2)(g) +O(g) " "` (fast equilibrium)
`O(g) +O_(3)(g) rarr 2O_(2)(g)" "` (slow)
Which rate law is consistent with this mechanism?

Ozone in the earth's atmosphere decomposes according to the equation: 2O_(3)(g) rarr 3O_(2)(g) This reaction is thought to occur via the two-step mechanism: Step 1: O_(3)(g) hArr O_(2)(g) +O(g) Fast, reversible Step 2: O_(3)(g) +O(g) rarr 2O_(2)(g) slow What rate law is consistent with this mechanism?

The conversion of ozne into oxygen is exotehrmin under what conditions is ozone is most stable? 2O_(3)(g)hArr3O_(2)(g)

The conversion of ozone into oxygen is exothermic . Under what conditions is ozone the most stable ? 2O_(3)(g)rArr3O_(2)(g)

The equilibrium constant of the reaction, SO_(3)(g) hArr SO_(2)(g)+1//2 O_(2)(g) is 0.15 at 900 K . Calculate the equilibrium constant for 2SO_(2)(g)+O_(2)(g) hArr 2SO_(3)(g)

For the first order reaction 2N_(2)O_(5)(g) rarr 4NO_(2)(g) + O_(2)(g)

Ozone deplection takes place as : 2O_(3)(g)rarr3O_(2)(g) Step1: O_(3)(g)overset(k)hArrO_(2)(g)+O(g)" " (fast) Step2 : O_(3)(g)+[O]overset(k)rarr2O_(2)(g)" " (slow) order of the raction will be :

If the equilibrium constant for N_(2) (g) + O_(2)(g) hArr 2NO(g) is K , the equilibrium " constant for " 1/2 N_(2) (g) +1/2 O_(2) (g) hArr NO (g) will be