The mechanism of the reaction
`2NO + O_(2) rarr 2NO_(2)` is
`NO + NO underset(k_(-1))overset(k_(1))hArr N_(2)O_(2) ("fast")`
`N_(2)O_(2) + O_(2) overset(k_(2))rarr 2NO_(2) (slow)`
The rate constant of the reaction is

For the gaseous reaction: N_(2)O_(4) rarr 2NO_(2)

4K_(2) Cr_(2) O_(7) overset(heat)rarr 4K_(2) CrO_(4) + 3O_(2) + X . In the above reaction X is

The forward reaction rate for the nitric oxide-oxygen reaction 2NO+O_(2) rarr 2NO_(2) has the rate law as: Rate = k[NO]^(2)[O_(2)] . If the mechanism is assumed to be: 2NO+O overset(k_(eq))hArr , (rapid equilibration) N_(2)O_(2) + O_(2) overset(k_(2))rarr 2NO_(2) (slow step), then which of the following is (are) correct? (I) Rate constant = k_(eq)k_(2) , (II) [N_(2)O_(2)] = k_(eq)[NO]^(2) (III) [N_(2)O_(2)] = k_(eq)[NO] , (IV) Rate constant = k_(2) The correct option is

Mechanism of the reaction is: A_(2) underset(k')overset(k)hArr 2A A + B_(2) overset(k_(2))rarr C + B B + A_(2) overset(k_(2))rarr C + A What is (-d[A_(2)])/(dt)

Conisder the reaction mechanism: A_(2) overset(k_(eq))hArr 2A ("fast") (where A is the intermediate.) A+B underset(k_(1))rarr P (slow) The rate law for the reaction is

Ozone depletion 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 reaction will be :

The depletion of ozone involves the following steps : Step 1 : O_3underset(K_1)overset(K_2)hArrO_2+O (fast) Step 2 : O_3+Ounderset(K)rarr2O_2 (slow) The predicted order of the reaction will be

Mechanism of the reaction is: A overset(k_(1))rarrB, 2Aoverset(k_(2))rarr C + D What is (-d[A])/(dt) ?

In the following reaction: 2NO(g)+O_(2)(g) overset(k')rarr2NO_(2)(g) What is the predicted rate law, if the mechanism is NO+O_(2)(g) overset(k_(eq))hArr NO_(3) ("fast") (fast) NO_(3) + NO overset(k_(1))rarr NO_(2) + NO_(2) (slow)

The reaction S_(2)O_(8)^(2-) + 3I^(ɵ) rarr 2SO_(4)^(2-) + I_(3)^(ɵ) is of first order both with respect to persulphate and iofide ions. Taking the initial concentration as a and b , respectively, and taking x as the concentration of the triofide at time t , a differential rate equation can be written. Two suggested mechanism for the reaction are: I. S_(2)O_(8)^(2-)+I^(ɵ) hArr SO_(4)I^(ɵ)+SO_(4)^(2-) ("fast") I^(ɵ)+SO_(4)I^(ɵ) overset(k_(1))rarrI_(2) + SO_(4)^(2-) (show) I^(ɵ) + I_(2) overset(k_(2))rarr I_(3)^(ɵ) ("fast") II. S_(2)O_(8)^(2-) + I^(ɵ) overset(k_(1))rarr S_(2)O_(8) I^(2-) (slow) S_(2)O_(8)I^(3-) overset(k_(2))rarr2SO_(4)^(2-)+I^(o+) ("fast") I^(o+) + I^(ɵ) overset(k_(3)) rarr I_(2) ("fast") I_(2) + I^(o+) overset(k_(4))rarr I_(3)^(ɵ) ("fast") The general difference equation for the above reaction is