Physical Chemistry Third Edition

(C. Jardin) #1

1102 26 Equilibrium Statistical Mechanics. II. Statistical Thermodynamics


version of Eq. (26.3-5) for each substance is substituted into Eq. (26.3-2) we obtain the
following equation for a reacting dilute gas mixture at equilibrium

0 

∑s

a 1

νa

[

ε 0 a−kBTln

(

z′a
Na

)]

(26.3-6)

where all of theε 0 values must be taken with respect to the same zero of energy. We
define∆ε 0 as the difference in the energies of the ground states of the product and
reactant molecules:

∆ε 0 

∑s

a 1

νaε 0 a (26.3-7)

This quantity is equal to the energy change whenνamolecules of substanceaappear if
ais a product, and|νa|molecules of substanceaare consumed ifais a reactant, with
all molecules in their ground states.
The sum of logarithms is the logarithm of a product. Use of the identity

yln(x)ln(xy) (26.3-8)

and division bykBTgives

0 

∆ε 0
kBT

−ln

[s

a 1

(

z′a
Na

)νa]
(26.3-9)

This equation can be manipulated into an equation containing the equilibrium constant.
The molecular partition functions are proportional toV, since the translational factor is

ztr

(

2 πmkBT
h^2

) 3 / 2

V (26.3-10)

and the other factors are independent ofV. We define

z′′a

z′a
V

(26.3-11)

so thatz′′ais independent ofV. Since dilute gases obey the ideal gas law,

V
Na



kBT
Pa



kBT
P◦

P◦

Pa



Vm◦
NAv

P◦

Pa

(26.3-12)

wherePais the partial pressure of substancea,NAvis Avogadro’s constant, andVm◦is
the volume occupied by 1.000 mol of ideal gas at the standard pressureP◦(exactly 1
bar) and temperatureT. Equation (26.3-9) can now be written as

0 

∆ε 0
kBT

−ln

[s

a 1

(

z′′aVm◦
NAv

)νa]
+ln

[ s

a 1

(

Pa
P◦

)νa]
(26.3-13)

The last term in this expression is the logarithm of the equilibrium constant in
Eq. (7.2-2). We can now write

ln(K)−

∆ε 0
kBT

+ln

[s

a 1

(

z′′aVm◦
NAv

)νa]
(26.3-14)
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