12.4 Reaction Mechanisms and Rate Laws 543
Equation (12.4-6) is now solved for [O]:
[O]K 1
[O 3 ]
[O 2 ]
This formula is substituted into Eq. (12.4-5) to obtain
d[O 2 ]
dt
∣
∣
∣
∣
step 2
2 k 2 [O 3 ][O] 2 k 2
k 1
k′ 1
[O 3 ]^2
[O 2 ]
2 k 2 K 1
[O 3 ]^2
[O 2 ]
We now write the rate law for the reaction by noting that step 1 produces one molecule
of O 2 for every two molecules produced by step 2:
rate
1
3
d[O 2 ]
dt
1
3
(
d[O 2 ]
dt
∣
∣
∣
∣
step 2
+
d[O 2 ]
dt
∣
∣
∣
∣
step 1
)
(
1
3
)(
3
2
)
d[O 2 ]
dt
∣
∣
∣
∣
step 2
(
1
3
)(
3
2
)
2 k 2
k 1
k′ 1
[O 3 ]^2
[O 2 ]
k 2 K 1
[O 3 ]^2
[O 2 ]
(12.4-7)
The forward rate of the first step exceeds the reverse rate by an amount equal to half
of the rate of step 2. Since both the forward and the reverse rate of the first step must
be large compared to the rate of the second step, the forward and reverse rates are still
nearly equal to each other. The concentration of O 2 (a product) occurs in this forward
rate law, which holds only if some O 2 is already present. In general a product will occur
in a forward rate law only if it is produced in a step prior to the rate-limiting step.
Exercise 12.9
For the gas-phase reaction
2NO+2H 2 −→N 2 +2H 2 O
the mechanism has been proposed
(1) 2NO+H 2 N 2 +H 2 O 2
(2) H 2 O 2 +H 2 −→2H 2 O
a.Find the rate law if the second step is rate-limiting.
b.Find the rate law if the reverse reaction of step 1 is omitted and this step is rate-limiting.
We can summarize the rate-limiting step approximation: If the first step is rate-
limiting, the rate law is the rate law of the first step. If a step after the first step is
rate-limiting, the rate law of the rate-limiting step is written. The concentrations of
any reactive intermediates in the rate law of the rate-limiting step are replaced by
expressions obtained by assuming that the steps prior to the rate-limiting step are at
equilibrium. The result is the final approximate rate law.
The Steady-State Approximation
This approximation, which is also called thequasi-steady-state approximation, con-
sists of the assumption that the rates of change of the concentrations of allreactive