1164 28 The Structure of Solids, Liquids, and Polymers
We can now write formulas for the thermodynamic functions of the Einstein model
using equations from Chapter 27:
UkBT^2
(
∂ln(Z)
∂T
)
V
U 0 + 3 NkBT^2
(
∂ln(z)
∂T
)
V
U 0 +
3 Nhν
ehν/kBT− 1
(28.2-7a)
CV
(
∂U
∂T
)
V,N
3 NkB
(
hν
kBT
) 2
ehν/kBT
(ehν/kBT−1)^2
(28.2-7b)
S
U
T
+kBln(Z)
U 0
T
+
3 Nhν
T(ehν/kBT)− 1
−
U 0
kBT
+ 3 NkBln(z)
3 Nhν
T(ehν/kBT−1)
− 3 NkBln
(
1 −e−hν/kBT
)
(28.2-7c)
A−kBTln(Z)U 0 + 3 NkBTln
(
1 −e−hν/kBT
)
(28.2-7d)
PkBT
(
∂ln(Z)
∂V
)
T
3 NkBT
(
ln(z)
∂V
)
T
(28.2-7e)
μ
(
∂A
∂N
)
T,V
≈
AN−AN− 1
1
U 0
N
+ 3 kBTln
(
1 −e−hν/kBT
)
(28.2-7f )
We use the chemical potential per molecule as in Chapter 26, not the chemical potential
per mole. We have replaced a derivative by a finite difference and have assumed thatU 0
for a crystal ofN−1 atoms is equal toU 0 for a crystal ofNatoms times (N−1)/N.
There is a difficulty with the pressure of the Einstein crystal model. The model does
not include any simple way to evaluate the derivative in Eq. (28.2-7e). We might try to
evaluate the pressure by finding the difference betweenGandA, sinceGA+PV.
For a one-component system,Gis given Eq. (26.1-29) as
GNμU 0 − 3 NkBTln(z)
U 0 + 3 NkBTln(1−e−hv/kBT) (28.2-7g)
so thatGA, which leads toPV0. This result is a shortcoming of a crude model,
but for a crystal the numerical value ofPVis small compared withGandA, so that
we can use the formulas forGandAto an adequate approximation.
The value of the frequencyνis determined by fitting the heat capacity formula to
experimental data. The formulas for the thermodynamic functions can be restated in
terms of the parameter
ΘE
hv
kB
(definition) (28.2-8)
The parameterΘEhas the dimensions of temperature and is called theEinstein
temperatureor thecharacteristic temperature. Figure 28.7 shows the heat capacity
of diamond as a function of temperature as well as the heat capacity of the Einstein
crystal model with an Einstein temperature of 1320 K, which gives the best fit to the
experimental data.
0
0.2
T/1320 K 5 T/QE
0.4 0.6 0.8 1.0
5
10
C
/V
J mol
21
K
21
15
20 Classical
Einstein
25
Figure 28.7 The Heat Capacity of
Diamond Fit to the Einstein Crys-
tal Model Result.The horizontal line
corresponds to the law of Dulong and
Petit. From J. S. Blakemore,SolidState
Physics, 2nd ed., W. B. Saunders,
Philadelphia, 1974, p. 121.
In the limit of high temperature
lim
T→∞
CV 3 NkB 3 nR (28.2-9)