Physical Chemistry Third Edition

(C. Jardin) #1
1106 26 Equilibrium Statistical Mechanics. II. Statistical Thermodynamics

vibrational partition functions≈1. Do your equilibrium
constants depend on temperature? Why or why not?
a. H 2 +D 2 2HD
b. HF+DDF+H

26.26Without doing any detailed calculations, estimate the
equilibrium constant for each of the gas-phase reactions.
State any assumptions. Do your equilibrium constants
depend on temperature? Why or why not?
a. HF+D 2 DF+HD
b. CH 4 +D 2 CH 3 D+HD


26.27Show that the equilibrium constant for a racemization
reaction equals unity.


26.28The ionization energy of the hydrogen atom is equal to
13.60 eV. Find the equilibrium constant for the
dissociation of a hydrogen atom into a proton and an
electron at 10000 K.


26.29Consider a hypotheticalcis–transisomerization in the gas
phase:
CT
Assume that the only important differences between the
two isomers are that one of the moments of inertia of the
transisomer is 8.3% higher than that of thecisisomer


and that one of the vibrational degrees of freedom has a
higher frequency in thecisisomer:

ν(trans) 6. 45 × 1013 s−^1
ν(cis) 7. 54 × 1013 s−^1

Assume that the ground-state energy of thecisisomer is
8.15× 10 −^21 J higher than that of thetransisomer. Find
the value of the equilibrium constant for this reaction at
500.0 K.
26.30Consider a substance that can exist in two tautomeric
forms, A and B. Define a partition function for the
combined forms
zzA+zB

where the same zero of energy (say the ground-state
energy of form A) must be used for both forms. Let the
energy of the ground state of form B be denoted byε0,B.
a.In terms ofzAandzB, what fraction of the molecules
will be form B? Form A?
b.In terms ofzAandzBwhat is the equilibrium constant
for the reaction
AB
How does this relate to the expression for the equilibrium
constant derived as in the chapter?

26.4 The Activated Complex Theory of

Bimolecular Chemical Reaction Rates in


Dilute Gases
We write the chemical equation for a hypothetical reaction as

aA+bB→dD+fF (26.4-1)

where the capital letters stand for chemical formulas and the lower-case letters represent
stoichiometric coefficients. We define the forward rate of the reaction, denoted byrf:

rf−

1

a

d[A]
dt

−

1

b

d[B]
dt

−

1

d

d[D]
dt



1

f

d[F]
dt

(definition ofrf) (26.4-2)

There is a large class of chemical reactions in which the forward reaction rate is
proportional to the concentration of each reactant raised to some power:

rf

1

a

d[A]
dt

kf[A]α[B]β (26.4-3)

Equation (26.4-3) is called arate law with definite orders. The proportionality con-
stantkfis called theforward rate constant. It is not a true constant. It depends on
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