28.3 The Electronic Structure of Crystalline Solids 1173
800 640
Au 4s
Au 4p1/2
Au 4p3/2
Au 5p3/2
Au 4d3/2,5/2
C 1s
Au 4f5/2,7/2
480
Binding energy/eV
320 160 0
Figure 28.10 X-Ray Photoelectron Spectrum of Gold.Each peak is labeled with the
subshell and the value ofJ, the quantum number for the total angular momentum. Courtesy
of Dr. Kevin Ogle.
of an upper band that is empty in the ground state. If the band gap between the lower
band and the upper band is not large compared withkBT, some electrons from the
lower-energy band will occupy states of the upper band and the crystal will conduct
some electricity. Figure 28.11 schematically depicts the band occupations in insulators,
conductors, and semiconductors.
Conductor
Large band gap
Insulator
Semiconductor
Small band gap
5 Empty states
5 Occupied states
Figure 28.11 Bands of Orbital
Energies in a Hypothetical Insula-
tor, Conductor, and Semiconductor.
The top figure, for an insulator, shows
the band gap, which is large compared
withkBT. The middle figure, for a
conductor, shows a partly filled band,
so that there is no band gap. The
bottom figure, for a semiconductor,
shows a band gap that is not large
compared withkBT.
T 2 >T 1
T 1 >0
T 50
f(^
)
5
1
Figure 28.12 The Fermion Probabil-
ity Distribution for 0 K and for Two
Nonzero Temperatures.
Electrons are fermions. If we neglect the interaction between the electrons the prob-
ability distribution of states is given by Eq. (26.5-4):
f(εi)
e(μ−εi)/kBT
1 +e(μ−εi)/kBT
1
e(εi−μ)/kBT+ 1
(28.3-1)
The value ofμ, the chemical potential of the electrons, is called theFermi level,
and is denoted byεF. At 0 K all of the states with energies at or below the Fermi
level will be fully occupied and those above the Fermi level will be vacant. If
the temperature is increased from 0 K, some of the states with energies just below
the Fermi level become unpopulated, and some of the states just above the Fermi
level become populated. The range of energy over which the probability distribution
ranges from roughly unity to nearly zero is approximately equal tokBT. Figure 28.12
schematically shows the fermion probability distribution for 0 K and for two nonzero
temperatures.
If the Fermi level lies at the top of a band or between two bands the crystal will be
an insulator at 0 K. If the band gap is not large compared withkBTfor some nonzero
temperature, some of the highest-energy states in the filled band will be vacant, some
of the low-lying states in the first vacant band will be occupied, and the crystal will