11.7 The Experimental Study of Fast Reactions 519
Exercise 11.23
a.Verify the steps of algebra leading to Eq. (11.7-7).
b.Verify that Eq. (11.7-8), with Eq. (11.7-9), is a solution to Eq. (11.7-7).
c.Write the expressions for∆[A] and∆[B].If we assume that hydrogen ions in water primarily occur as hydronium ions, the
reaction of hydrogen ions and hydroxide ions can be writtenH 3 O++OH−
k 1
k′ 12H 2 O (11.7-10)
which has the general formA+B
k 1
k′ 12C (11.7-11)
Assume that the reaction is second order in both directions. We write[C][C]eq+∆[C] (11.7-12a)[A][A]eq−1
2
∆[C] (11.7-12b)[B][B]eq−1
2
∆[C] (11.7-12c)When Eqs. (11.7-12) are substituted into the differential equation for the rate of the
reaction and the necessary steps of algebra are carried out with neglect of terms pro-
portional to (∆[C])^2 , we obtain∆[C]∆[C] 0 e−t/τ (11.7-13)where1
τk 1[A]eq+[B]eq
2+ 2 k′ 1 [C]eq (11.7-14)EXAMPLE11.12
At 25◦C, the forward rate constant of Eq. (11.7-10) is equal to 1. 4 × 1011 L mol−^1 s−^1 .At
this temperature, the dissociation equilibrium constantKwequals 1. 008 × 10 −^14 mol^2 L−^2.
a.Using Eq. (11.5-3), find the value ofk′ 1.
b.For pure water, find the relaxation time if a T-jump experiment has a final temperature of
25 ◦C.
Solution
a.We convertKw, for which the H 2 O activity is expressed in terms of the mole fraction, to
the equilibrium constant for the reaction of Eq. (11.7-10) with all concentrations in terms
of molarities: