282 4 Thermodynamics and Statistical Physics
LetP(E) be the probability function which gives the probability of the state
at the energyEto be occupied. AtT=0 all states below a certain energy are
filled (P=1) and all states above that energy are vacant (P=0). The highest
occupied state under the given conditions is called the Fermi energy.
The product of the densityn(E) of available states and the probabilityP(E)
that those states are occupied, gives the density of occupied statesn 0 (E);
that is
n 0 (E)=n(E)P(E)
The total number of occupied states per unit volume is given byn=∫EF
0n 0 (E)dE=
8
√
2 πm^3 /^2
h^3∫EF
0E^1 /^2 d(E)=
8
√
2 πm^3 /^2
h^3.
2
3
E^3 F/^2
or EF=h^2
8 m(
3 n
π) 2 / 3
4.54 P+=
1
e(E−EF)/kT+ 1=
1
eΔ/kT+ 1≈
1
2 +Δ/kT=
1
2
(1−Δ/ 2 kT)P−=1
2
(1+Δ/ 2 kT)∴P++P−
2
= 1 / 2 =PF
4.55 (a) Fornstates, the number of ways isN=n^2. Therefore, forn=6 states
N= 36
(b) Fornstates the number of ways isN=n^2 −(n−1)or n^2 −n+1. Therefore,
forn= 6 ,N= 31
(c) Fornstates,N=n^2 −n+ 1 −norn^2 − 2 n+1. Therefore forn=6,
N= 254.56 If the gas is in equilibrium, the number of particles in a vibrational state is
Nν=N 0 exp(
−
hν
kT)
=N 0 exp(
−
θ
T)
.
The ratios,N 0 /N 1 = 4. 7619 ,N 1 /N 2 = 4. 8837 ,N 2 /N 3 = 4 .7778, are seen
to be constant at 4.8078. Thus the ratioNν/Nν+ 1 is constant equal to 4.81,
showing the gas to be in equilibrium at a temperature
T= 3 , 350 /(ln 4.81)≈ 2 ,130 K4.57ΔS=kln(ΔW)
ButΔS=ΔQ/T