Light Emitting Diode2.232000/08/072008/05/28 15:47:32.996 GMT-5BillWilsonwlw@madriver.netBillWilsonwlw@madriver.netElizabethGregoryelizabeth.gregory@gmail.comJeffreyMSilvermanJSilverman@astro.berkeley.eduGerardWysockigerardw@rice.eduScottWKravitzswkravitz@gmail.comdiodelight emitting diodeLight Emitting Diode Let's talk about the recombining electrons
for a minute. When the electron falls down from the conduction
band and fills in a hole in the valence band, there is an
obvious loss of energy. The question is; where does that energy
go? In silicon, the answer is not very interesting. Silicon is
what is known as an indirect band-gap material.
What this means is that as an electron goes from the bottom of
the conduction band to the top of the valence band, it must also
undergo a significant change in momentum. This all comes about
from the details of the band structure for the material, which
we will not concern ourselves with here. As we all know,
whenever something changes state, we must still conserve not
only energy, but also momentum. In the case of an electron
going from the conduction band to the valence band in silicon,
both of these things can only be conserved if the transition
also creates a quantized set of lattice vibrations, called
phonons, or "heat". Phonons posses
both energy and momentum, and their
creation upon the recombination of an electron and hole allows
for complete conservation of both energy and momentum. All of
the energy which the electron gives up in going from the
conduction band to the valence band (1.1 eV) ends up in phonons,
which is another way of saying that the electron heats up the
crystal.
In some other semiconductors, something else
occurs. In a class of materials called direct band-gap
semiconductors, the transition from conduction band to
valence band involves essentially no change in momentum.
Photons, it turns out, possess a fair amount of energy (several
eV/photon in some cases) but they have very little momentum
associated with them. Thus, for a direct band gap material, the
excess energy of the electron-hole recombination can either be
taken away as heat, or more likely, as a photon of light. This
radiative transition then conserves energy and
momentum by giving off light whenever an electron and hole
recombine. This gives rise to (for us) a new type of device,
the light emitting diode (LED). Emission of a photon in an LED
is shown schematically in .
Radiative recombination in a direct band-gap semiconductor
It was Planck who postulated that the energy of a photon was
related to its frequency by a constant, which was later named
after him. If the frequency of oscillation is given by the
Greek letter "nu" (ν), then the
energy of the photon is just
hν, where h is Planck's
constant, which has a value of
4.14-15eVseconds.
Ehν
When we talk about light it is conventional to specify its
wavelength, λ, instead of
its frequency. Visible light has a wavelength on the order of
nanometers (Red is about 600 nm, green about 500 nm and blue is
in the 450 nm region.) A handy "rule of thumb" can be derived
from the fact that
λcv, where c is the speed of
light. Since
c38msec or
c317nmsecλnmhcEeV1242EeV Thus, a semiconductor with a 2 eV band-gap should
give off light at about 620 nm (in the red). A 3 eV band-gap
material would emit at 414 nm, in the violet. The human eye, of
course, is not equally responsive to all colors. We show
this in , where we have also included the
materials which are used for important light emitting diodes
(LEDs) for each of the different spectral regions.
Relative response of the human eye to various colors
As you no doubt notice, a number of the important LEDs are based
on the GaAsP system. GaAs is a direct band-gap semiconductor
with a band gap of 1.42 eV (in the infrared). GaP is an
indirect band-gap material with a band gap of 2.26 eV (550 nm,
or green). Both As and P are group V elements. (Hence the
nomenclature of the materials as III-V compound
semiconductors.) We can replace some of the As with P in
GaAs and make a mixed compound semiconductor
GaAs1-xPx. When the mole fraction of phosphorous is less than
about 0.45 the band gap is direct, and so we can "engineer" the
desired color of LED that we want by simply growing a crystal
with the proper phosphorus concentration! The properties of the
GaAsP system are shown in . It turns
out that for this system, there are actually
two different band gaps, as shown in the
inset. One is a direct gap (no
change in momentum) and the other is indirect. In GaAs, the
direct gap has lower energy than the indirect one (like in the
inset) and so the transition is a radiative one. As we start
adding phosphorous to the system, both the direct and indirect
band gaps increase in energy. However, the direct gap energy
increases faster with phosphorous fraction than does the
indirect one. At a mole fraction
x of about 0.45, the gap energies
cross over and the material goes from being a direct gap
semiconductor to an indirect gap semiconductor. At
x0.35 the band gap is about 1.97 eV (630 nm), and so we
would only expect to get light up to the red using the GaAsP
system for making LED's. Fortunately, people discovered that
you could add an impurity (nitrogen) to the GaAsP system, which
introduced a new level in the system. An electron could go from
the indirect conduction band (for a mixture with a mole fraction
greater than 0.45) to the nitrogen site, changing its momentum,
but not its energy. It could then make a direct transition to
the valence band, and light with colors all the way to the green
became possible. The use of a nitrogen recombination
center is depicted in the .
Band gap for the GaAsP system
Addition of a nitrogen recombination center to indirectGaAsP
If we want colors with wavelengths shorter than the green, we
must abandon the GaAsP system and look for more suitable
materials. A compound semiconductor made from the II-VI
elements Zn and Se make up one promising system, and several
research groups have successfully made blue and blue-green LEDs
from ZnSe. SiC is another (weak) blue emitter which is
commercially available on the market. Recently, workers at a
tiny, unknown chemical company stunned the "display world" by
announcing that they had successfully fabricated a blue LED
using the II-V material GaN. A good blue LED has been the "holy
grail" of the display and CD ROM research community for a number
of years now. Obviously, adding blue to the already working
green and red LED's completes the set of 3 primary colors
necessary for a full-color flat panel display (Hang a TV screen
on your wall like a picture?). Using a blue LED or laser in a
CD ROM would more than quadruple its data capacity, as bit
diameter scales as λ, and
hence the area as
λ2.