1110 26 Equilibrium Statistical Mechanics. II. Statistical Thermodynamics
motion along the reaction coordinate and leads to dissociation to form either products
or reactants, since the potential energy is at a maximum instead of a minimum along
the reaction coordinate.
We write the partition function of the activated complex in the form
z′′CDFz‡CDF′′ zrc (26.4-9)
wherezrcis the factor in the partition function corresponding to motion along the
reaction coordinate and wherez
‡′′
CDFrepresents the translational factor, the rotational
factor, the electronic factor, and the three vibrational factors.
We adopt a nonrigorous approach to obtain a formula forzrc. We pretend that we
can change the potential energy surface so that the asymmetric stretch is like that of a
triatomic molecule in Figure 26.2. The partition function for the reaction coordinate is
now that for an asymmetric stretch:
zrc
1
1 −e−hνas/kBT
(26.4-10)
whereνasis the frequency of oscillation of the asymmetric stretch. We now let the
potential energy surface become flatter in theabcdirection. As its curvature in the
direction of the reaction coordinate becomes small,νasbecomes small, and we can use
the approximatione−x≈ 1 −x, which gives
zrc
1
1 −(1−hνas/kBT)
kBT
hνas
(26.4-11)
The frequency of the asymmetric stretch,νas, gives the number of oscillations per
second in the direction of the asymmetric stretch, which becomes the direction of the
reaction coordinate in this limit. We assume that we can identifyνaswithνpassage, and
write
νpassage
kBT
hzrc
(26.4-12)
This process of mentally distorting the potential energy surface is not very satisfactory
because the process must be continued until the curvature becomes negative in order
to recover the actual surface. There are better ways to derive Eq. (26.4-12) that lead to
the same result.^8
The concentration of the activated complex is given by Eqs. (26.4-8), (26.4-9), and
(26.4-12):
[CDF‡]e−∆ε
‡
0 /kBT
z
‡′′
CDFzrc
z′′CDz′′F
NAv[CD][F] (26.4-13)
The rate of the reaction is given by
Rateνpassage[CDF‡]
kBT
hzrc
e−∆ε
‡
0 /kBT
z
‡′′
CDFzrc
z′′CDzF
NAv[CD][F]
kBT
h
e−∆ε
‡
0 /kBT
z‡CDF′′
z′′CDz′′F
NAv[CD][F] (26.4-14)
(^8) K. J. Laidler,Chemical Kinetics, 3rd ed., HarperCollins, New York, 1987, p. 97ff.