532 12 Chemical Reaction Mechanisms I: Rate Laws and Mechanisms
Solution reactions that are much slower than diffusion-limited reactions are called
activation-limited reactions. After an encounter occurs, the molecules undergo numer-
ous collisions inside a “cage” of other molecules before finally reacting. The rate of
collisions is very large (see Example 9.12), but only a small fraction of them will
lead to reaction. If this fraction depends only on the temperature, the rate will be
proportional to the number of encounters as well as to the fraction of collisions that lead
to reaction. Since the number of 2–3 encounters is proportional to the number of type
2 molecules and the number of type 3 molecules, an activation-limited bimolecular
elementary reaction is first order with respect to each reactant and second order
overall, just as with a diffusion-limited reaction and a gas-phase reaction. The rate of
a reaction between molecules of the same substance is second order with respect to
that substance, and its temperature dependence should be similar to that of a gas-phase
reaction.
Termolecular and Unimolecular Liquid-Phase Reactions
The rates of diffusion-limited termolecular elementary processes in liquid phases
are proportional to the number of encounter pairs (pairs of molecules in the midst
of an encounter) and also to the number of “third” molecules present to diffuse
into the same cage as the encounter pair. Therefore, diffusion-limited termolecular
elementary processes are third order, just as in the gas phase. Activation-limited
termolecular elementary reactions in liquids are also third order if the fraction of
collisions that lead to reaction is independent of the concentration. We assume further
that unimolecular elementary processes in liquids exhibit first-order kinetics, as in
the gas phase. We can now summarize the facts for elementary processes in both
liquids and gases:The molecularity of a substance in an elementary process is equal
to its order, and the overall order is equal to the sum of the orders of the individual
substances.
PROBLEMS
Section 12.2: Elementary Processes in Liquid Solutions
12.1 The reaction
2I−→I 2
is diffusion-controlled in carbon tetrachloride and also in
water. Estimate the rate constant of the reaction in water at
20 ◦C from data in Example 12.3 and from viscosities in
Table A.18 of Appendix A.
12.2 The reaction in aqueous solution
NH+ 4 +OH−−→NH 3 +H 2 O
is diffusion-controlled with rate constant equal to
1. 0 × 1010 L mol−^1 s−^1 at some temperature. Estimate the
sum of the diffusion coefficients of NH+ 4 and OH−at this
temperature.
12.3 Compute the reaction diameterd 12 for the reaction
CH 3 CO− 2 +H+−→CH 3 CO 2 H
for whichk 4. 5 × 1010 L mol−^1 s−^1. Use the values of
the ion mobilities from Table A.20 of Appendix A.
12.4 a.The reaction
2CH 3 −→C 2 H 6
in toluene is diffusion-controlled. The viscosity of
toluene at 30◦C is equal to 5. 236 × 10 −^4 kg m−^1 s−^1.
Estimate the rate constant of the reaction. State any
assumptions.
b.The viscosity of toluene at 20◦C is equal to 5. 9 ×
10 −^4 kg m−^1 s−^1. Estimate the activation energy of the