1144 27 Equilibrium Statistical Mechanics. III. Ensembles
Exercise 27.7
a.Show that the vibrational energy given by Eq. (26.2-8) approaches the equipartition value
ofNkBTnRTfor large values ofT. However, remember that this equation is not valid
for large values ofTsince the molecule would dissociate for large values of the vibrational
energy.
b.Calculate the vibrational energy of 1.000 mol of Br 2 at 298.15 K and at 1000.0 K. Compare
your result withRTfor each temperature.
c.Repeat the calculation of part b for H 2.
The Entropy of a Dilute Gas
We apply Eq. (27.5-4) to a dilute gas:
S
U
T
+kBln(Zcl)
U
T
+kBln(zNcl)
U
T
+NkBln(zcl) (27.5-17)
As previously stated, the classical molecular partition function has units of kg m^2 s−^1
raised to some power, so a divisor with units must be included to make the argument
of the logarithm dimensionless. If a divisor of 1 kg m^2 s−^1 is used, values are
obtained for the entropy and the Helmholtz energy that differ from the experimental
values. However, when the classical canonical translational partition function is
divided by h^3 NN! and Stirling’s approximation is used for ln(N!), the same formulas
are obtained as Chapter 26. For a dilute monatomic gas the corrected classical
formula is
S
U
T
+NkBln
(z
cl
Nh^3
)
+NkB
U
T
+NkBln
(z
qm
N
)
+NkB (27.5-18)
which is the same as Eq. (26.1-5).
Equation (27.5-18) also holds for the translational contribution to the entropy of
molecular substances. For a diatomic substance the rotational contribution to the
entropy with a unit divisor would be
Srot,cl
Urot
T
+NkBln(zrot,cl) (27.5-19)
With a divisor ofσh^2 , whereσis the symmetry number,
Srot
Urot
T
+NkBln
(z
rot,cl
σh^2
)
Urot
T
+NkBln(zrot,qm) (27.5-20)
which is also identical to the formula from quantum statistical mechanics. A similar
formula holds for polyatomic dilute gases, with division byσh^3 instead of byσh^2.
EXAMPLE27.4
a.Calculate the rotational contribution to the entropy of 1.000 mol of Cl 2 gas at 298.15 K,
using the formula of Eq. (27.5-19).
b.Repeat the calculation of part a using the corrected formula of Eq. (27.5-20).
c.Show that the difference between the result of part a and part b would be the same for any
temperature.