Physical Chemistry Third Edition

(C. Jardin) #1
1114 26 Equilibrium Statistical Mechanics. II. Statistical Thermodynamics

where the equilibrium constantK

cand the standard-state Gibbs energy change∆G‡


are for the formation of the activated complex excluding the motion along the reaction
coordinate.

SvanteArrhenius,1859–1927,wasa
Swedish chemist who wonthe 1905
Nobel Prize inchemistry for his theory
ofdissociationandionizationof
electrolytes insolution.


There is an empirical formula that represents the temperature dependence of rate
constants, due to Arrhenius:

kAe−Ea/RT (26.4-17)

whereEais a parameter called the activation energy. The activation energyEais
sometimes defined as

EaRT^2

dln(k)
dT

(26.4-18)

Exercise 26.13
Show that Eq. (26.4-18) is compatible with Eq. (26.4-17) ifAis constant.

Differentiation of the natural logarithm ofkas represented in the first equality of
Eq. (26.4-16) gives

EaRT^2

(

dln(T)
T

+

dln(K‡c)
dT

)

(26.4-19)

From Eq. (7.6-4)

(

∂ln(K)
∂T

)

P

−

(

∂∆G◦/RT

∂T

)

P



∆G◦

RT^2

+

1

RT

(

∂∆G◦

∂T

)

P


∆G◦

RT^2

+

1

RT

∆S◦

∆H◦

RT^2

(26.4-20)

so that

EaRT+∆H◦‡ (26.4-21)

Using this relation and the relation∆G∆H−T∆S, which holds for isothermal
processes, Eq. (26.4-16) can be rewritten

k

kBT
h

1

c◦

e∆S

‡◦/R
e−∆H

‡◦/RT


kBT
h

1

c◦

e^1 e∆S

‡◦/R
e−Ea/RT (26.4-22)

The Arrhenius preexponential factor corresponds to the transition-state preexponential
factor

Ats

kBT
h

1

c◦e

e∆S

‡◦/R
(26.4-23)

The Arrhenius preexponential factor is temperature-independent, butAtsdepends on
the temperature. However, if we setAtsequal to the Arrhenius preexponential factor
we can relate∆S‡


to the Arrhenius preexponential factor.
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