404 Quantum ensembles
Q(β) =∑∞
n=0e−βEn=∑∞
n=0e−β(n+1/2) ̄hω. (10.4.17)Recalling that the sum of a geometric series is given by
∑∞n=0rn=1
1 −r, (10.4.18)
where 0< r <1, the partition function becomes
Q(β) = e−β ̄hω/^2∑∞
n=0e−nβhω ̄ = e−β ̄hω/^2∑
n=0(
e−βhω ̄)n
=e−β ̄hω/^2
1 −e−β ̄hω. (10.4.19)
From the partition function, various thermodynamic quantities canbe determined.
First, the free energy is given by
A=−
1
β
lnQ(β) =̄hω
2+
1
β
ln(
1 −e−β ̄hω)
, (10.4.20)
while the total energy is
E=−
∂
∂βlnQ(β) =̄hω
2+
̄hωe−β ̄hω
1 −e−β ̄hω=
(
1
2
+〈n〉)
̄hω. (10.4.21)Thus, even if〈n〉= 0, there is still a finite amount of energy, ̄hω/2 in the system. This
residual energy is known as thezero-point energy. Next, from the average energy, the
heat capacity can be determined
C
k=
(β ̄hω)^2 e−β ̄hω
(1−e−β ̄hω)^2. (10.4.22)
Note that as ̄h→0,C/k→1 in agreement with the classical result. Finally, the
entropy is given by
S=klnQ(β) +E
T
=−kln(
1 −e−β ̄hω)
+
̄hω
Te−β ̄hω
1 −e−β ̄hω, (10.4.23)
which is consistent with the third law of thermodynamics, asS→0 asT→0.
The expressions we have derived for the thermodynamic observables are often used
to estimate thermodynamic quantities of molecular systems under the assumption
that the system can be approximately decomposed into a set of uncoupled harmonic
oscillators corresponding to the normal modes of Section 1.7. By summing the expres-
sions in eqns. (10.4.20), (10.4.22), or (10.4.23) over a set of frequencies generated in
a normal-mode calculation, estimates of the quantum thermodynamic properties such
as free energy, heat capacity, and entropy, can be easily obtained.
As a concluding remark, we note that the formulation of the quantum equilibrium
ensembles in terms of the eigenvalues and eigenvectors ofHˆsuggests that the computa-
tional problems inherent in many-body quantum mechanics have notbeen alleviated.