5.3 Solutions 307
(b) p(E)=
1
e−^1.^932 + 1
= 0. 873
(c) p(E)=
1
e^0 + 1
= 0. 5
5.28 Assuming that the Fermi energy is to be at the middle of the gap between the
conduction and valence bands,E−EF=^1 / 2 Eg
p(E)=
1
e(E−EF)/kT+^1
=
1
eEg/^2 kT+ 1
The factorEg/ 2 kT=
1. 1
2 × 8. 625 × 10 −^5 × 400
= 15. 942
p(E)≈e−^15.^942 = 8. 4 × 10 −^6
5.29 The Debye temperatureθis
θ=
hνm
k
νm=
k
h
θ=
1. 38 × 10 −^23 × 360
6. 625 × 10 −^34
= 7. 5 × 1012 Hz
5.30 (a) At high temperaturesT>> θE, in the denominator (eθE/T−1)^2 ≈θE^2 /T^2 ,
and in the numeratoreθE/T→1, so thatCv→ 3 N 0 k= 3 R, the Dulong –
Petit’s value
(b) When the temperature is very lowT << θE, and in the bracket of the
denominator, 1 is negligible in comparison with the exponential term.
Therefore,Cv → 3 R(θE/T)^2 e−θE/T. Thus the specific heat goes to zero
asT →0. However, the experimentally observed specific heats at low
temperatures decrease more gradually than the exponential decrease sug-
gested by Einstein’s formula.
5.31Cv=
9 R
x^3
∫x
0
ξ^4 eξ
(eξ−1)^2
dξ (1)
This equation may be integrated by parts,
∫x
0
ξ^4 eξ
(eξ−1)^2
dξ=−
∫
ξ^4
d
dξ
(
1
eξ− 1
)
dξ
=−ξ^4
1
eξ− 1
+
∫
1
eξ− 1
dξ^4
dξ
dξ
=−ξ^4
1
eξ− 1
+ 4
∫
ξ^3
eξ− 1
dξ
Thus (1) becomes
Cv= 9 R
[
4
x^3
∫x
0
ξ^3
eξ− 1
dξ−
x
ex− 1