Harmonic systems 95where ̄h=h/ 2 π. The integration overI′now proceeds using eqn. (A.2) and yields
unity, so that
Ω(E) =E 0
̄hω. (3.6.11)
Interestingly, Ω(E) is a constant independent ofE. All one-dimensional harmonic
oscillators of frequencyωhave the same number of accessible microstates! Thus, no
interesting thermodynamic properties can be derived from this partition function, and
the entropySis simply a constantkln(E 0 / ̄hω).
Consider next a collection ofN independent harmonic oscillators with different
masses and force constants, for which the Hamiltonian is
H=
∑N
i=1[
p^2 i
2 mi+
1
2
kir^2 i]
. (3.6.12)
For this system, the microcanonical partition function is
Ω(N,E) =
E 0
h^3 N∫
dNpdNrδ(N
∑
i=1[
p^2 i
2 mi+
1
2
kir^2 i]
−E
)
. (3.6.13)
Since the oscillators are all different, theN! factor is not needed. Let us first introduce
scaled variables according to
yi=
pi
√
2 miui=√
ki
2ri, (3.6.14)so that the partition function becomes
Ω(N,E) =
23 NE 0
h^3 N∏N
i=11
ωi^3∫
dNydNuδ(N
∑
i=1(
y^2 i+u^2 i)
−E
)
, (3.6.15)
whereωi=
√
ki/miis the natural frequency for each oscillator. As in the ideal gasexample, we recognize that the condition
∑N
i=1(y2
i+u
2
i) =Edefines a (6N−1)-
dimensional spherical surface, and we may introduce 6N-dimensional spherical coor-
dinates to yield
Ω(N,E) =
8 E 0
h^3 N∏N
i=11
ω^3 i∫
d^6 N−^1 ω ̃∫∞
0dR R^6 N−^1 δ(
R^2 −E
)
. (3.6.16)
Using eqn. (3.5.14) and eqn. (A.15) allows the integration to be carried out in full with
the result:
Ω(N,E) =23 NE 0 π^3 N
Eh^3 NEN
Γ(3N)
∏N
i=11
ω^3 i. (3.6.17)
In the thermodynamic limit, 3N− 1 ≈ 3 N, and we can neglect the prefactorE 0 /E,
leaving