Semiconductor Electronics: Materials, Devices, and Simple Circuits PDF

Summary

This material introduces semiconductor electronics, discussing semiconductor physics, device classification, and basic circuits. It covers the difference between metals, semiconductors, and insulators and provides foundational knowledge for semiconductor devices.

Full Transcript

Chapter Fourteen

SEMICONDUCTOR

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ELECTRONICS:
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MATERIALS, DEVICES
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AND SIMPLE CIRCUITS
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14.1 INTRODUCTION
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Devices in which a controlled flow of electrons can be obtained are the
basic building blocks of all the electronic circuits. Before the discovery of
transistor in 1948, such devices were mostly vacuum tubes (also called
valves) like the vacuum diode which has two electrodes, viz., anode (often
called plate) and cathode; triode which has three electrodes – cathode,
plate and grid; tetrode and pentode (respectively with 4 and 5 electrodes).
In a vacuum tube, the electrons are supplied by a heated cathode and
the controlled flow of these electrons in vacuum is obtained by varying
the voltage between its different electrodes. Vacuum is required in the
inter-electrode space; otherwise the moving electrons may lose their
energy on collision with the air molecules in their path. In these devices
the electrons can flow only from the cathode to the anode (i.e., only in one
direction). Therefore, such devices are generally referred to as valves.
no

These vacuum tube devices are bulky, consume high power, operate
generally at high voltages (~100 V) and have limited life and low reliability.
The seed of the development of modern solid-state semiconductor
electronics goes back to 1930’s when it was realised that some solid-
state semiconductors and their junctions offer the possibility of controlling
the number and the direction of flow of charge carriers through them.
Simple excitations like light, heat or small applied voltage can change
the number of mobile charges in a semiconductor. Note that the supply
 Physics
and flow of charge carriers in the semiconductor devices are within the
solid itself, while in the earlier vacuum tubes/valves, the mobile electrons
were obtained from a heated cathode and they were made to flow in an
evacuated space or vacuum. No external heating or large evacuated space
is required by the semiconductor devices. They are small in size, consume
low power, operate at low voltages and have long life and high reliability.

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Even the Cathode Ray Tubes (CRT) used in television and computer
monitors which work on the principle of vacuum tubes are being replaced
by Liquid Crystal Display (LCD) monitors with supporting solid state

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electronics. Much before the full implications of the semiconductor devices
was formally understood, a naturally occurring crystal of galena (Lead
sulphide, PbS) with a metal point contact attached to it was used as
detector of radio waves.

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In the following sections, we will introduce the basic concepts of
semiconductor physics and discuss some semiconductor devices like
re R junction diodes (a 2-electrode device) and bipolar junction transistor (a

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3-electrode device). A few circuits illustrating their applications will also
be described.
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14.2 CLASSIFICATION OF METALS, C ONDUCTORS AND
SEMICONDUCTORS
be C

On the basis of conductivity
On the basis of the relative values of electrical conductivity ( σ ) or resistivity
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( ρ = 1/σ ), the solids are broadly classified as:
(i) Metals: They possess very low resistivity (or high conductivity).
ρ ~ 10–2 – 10–8 Ω m
σ ~ 102 – 108 S m–1
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(ii) Semiconductors: They have resistivity or conductivity intermediate
to metals and insulators.
ρ ~ 10–5 – 106 Ω m
σ ~ 105 – 10–6 S m–1
(iii)Insulators: They have high resistivity (or low conductivity).
ρ ~ 10 11 – 1019 Ω m
σ ~ 10–11 – 10–19 S m–1
The values of ρ and σ given above are indicative of magnitude and
could well go outside the ranges as well. Relative values of the resistivity
are not the only criteria for distinguishing metals, insulators and
semiconductors from each other. There are some other differences, which
will become clear as we go along in this chapter.
Our interest in this chapter is in the study of semiconductors which
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could be:
(i) Elemental semiconductors: Si and Ge
(ii) Compound semiconductors: Examples are:
Inorganic: CdS, GaAs, CdSe, InP, etc.
Organic: anthracene, doped pthalocyanines, etc.
Organic polymers: polypyrrole, polyaniline, polythiophene, etc.
Most of the currently available semiconductor devices are based on
468 elemental semiconductors Si or Ge and compound inorganic
 Semiconductor Electronics:
Materials, Devices and
Simple Circuits
semiconductors. However, after 1990, a few semiconductor devices using
organic semiconductors and semiconducting polymers have been
developed signalling the birth of a futuristic technology of polymer-
electronics and molecular-electronics. In this chapter, we will restrict
ourselves to the study of inorganic semiconductors, particularly
elemental semiconductors Si and Ge. The general concepts introduced
here for discussing the elemental semiconductors, by-and-large, apply

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to most of the compound semiconductors as well.

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On the basis of energy bands
According to the Bohr atomic model, in an isolated atom the energy of
any of its electrons is decided by the orbit in which it revolves. But when
the atoms come together to form a solid they are close to each other. So

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the outer orbits of electrons from neighbouring atoms would come very

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close or could even overlap. This would make the nature of electron motion
in a solid very different from that in an isolated atom.
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Inside the crystal each electron has a unique position and no two

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electrons see exactly the same pattern of surrounding charges. Because
of this, each electron will have a different energy level. These different
energy levels with continuous energy variation form what are called
E
energy bands. The energy band which includes the energy levels of the
valence electrons is called the valence band. The energy band above the
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valence band is called the conduction band. With no external energy, all
the valence electrons will reside in the valence band. If the lowest level in
the conduction band happens to be lower than the highest level of the
valence band, the electrons from the valence band can easily move into
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the conduction band. Normally the conduction band is empty. But when
it overlaps on the valence band electrons can move freely into it. This is
the case with metallic conductors.
If there is some gap between the conduction band and the valence
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band, electrons in the valence band all remain bound and no free electrons
are available in the conduction band. This makes the material an
insulator. But some of the electrons from the valence band may gain
external energy to cross the gap between the conduction band and the
valence band. Then these electrons will move into the conduction band.
At the same time they will create vacant energy levels in the valence band
where other valence electrons can move. Thus the process creates the
possibility of conduction due to electrons in conduction band as well as
due to vacancies in the valence band.
Let us consider what happens in the case of Si or Ge crystal containing
N atoms. For Si, the outermost orbit is the third orbit (n = 3), while for Ge
it is the fourth orbit (n = 4). The number of electrons in the outermost
orbit is 4 (2s and 2p electrons). Hence, the total number of outer electrons
in the crystal is 4N. The maximum possible number of electrons in the
no

outer orbit is 8 (2s + 6p electrons). So, for the 4N valence electrons there
are 8N available energy states. These 8N discrete energy levels can either
form a continuous band or they may be grouped in different bands
depending upon the distance between the atoms in the crystal (see box
on Band Theory of Solids).
At the distance between the atoms in the crystal lattices of Si and Ge,
the energy band of these 8N states is split apart into two which are
separated by an energy gap Eg (Fig. 14.1). The lower band which is 469
 Physics
completely occupied by the 4N valence electrons at temperature of absolute
zero is the valence band. The other band consisting of 4N energy states,
called the conduction band, is completely empty at absolute zero.

B AND THEORY OF SOLIDS

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Consider that the Si or Ge crystal
contains N atoms. Electrons of each
atom will have discrete energies in

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different orbits. The electron energy
will be same if all the atoms are
isolated, i.e., separated from each
other by a large distance. However,

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in a crystal, the atoms are close to

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each other (2 to 3 Å) and therefore
the electrons interact with each
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neighbouring atomic cores. The
overlap (or interaction) will be more
E
felt by the electrons in the
outermost orbit while the inner
orbit or core electron energies may
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remain unaffected. Therefore, for understanding electron energies in Si or Ge crystal, we
need to consider the changes in the energies of the electrons in the outermost orbit only.
For Si, the outermost orbit is the third orbit (n = 3), while for Ge it is the fourth orbit
(n = 4). The number of electrons in the outermost orbit is 4 (2s and 2p electrons). Hence,
o N

the total number of outer electrons in the crystal is 4N. The maximum possible number of
outer electrons in the orbit is 8 (2s + 6p electrons). So, out of the 4N electrons, 2N electrons
are in the 2N s-states (orbital quantum number l = 0) and 2N electrons are in the available
6N p-states. Obviously, some p-electron states are empty as shown in the extreme right of
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Figure. This is the case of well separated or isolated atoms [region A of Figure].
Suppose these atoms start coming nearer to each other to form a solid. The energies
of these electrons in the outermost orbit may change (both increase and decrease) due to
the interaction between the electrons of different atoms. The 6N states for l = 1, which
originally had identical energies in the isolated atoms, spread out and form an energy
band [region B in Figure]. Similarly, the 2N states for l = 0, having identical energies in
the isolated atoms, split into a second band (carefully see the region B of Figure) separated
from the first one by an energy gap.
At still smaller spacing, however, there comes a region in which the bands merge with
each other. The lowest energy state that is a split from the upper atomic level appears to
drop below the upper state that has come from the lower atomic level. In this region (region
C in Figure), no energy gap exists where the upper and lower energy states get mixed.
Finally, if the distance between the atoms further decreases, the energy bands again
split apart and are separated by an energy gap Eg (region D in Figure). The total number
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of available energy states 8N has been re-apportioned between the two bands (4N states
each in the lower and upper energy bands). Here the significant point is that there are
exactly as many states in the lower band (4N) as there are available valence electrons
from the atoms (4N ).
Therefore, this band ( called the valence band ) is completely filled while the upper
band is completely empty. The upper band is called the conduction band.

470
 Semiconductor Electronics:
Materials, Devices and
Simple Circuits
The lowest energy level in the
conduction band is shown as E C and
highest energy level in the valence band
is shown as EV. Above E C and below EV
there are a large number of closely spaced
energy levels, as shown in Fig. 14.1.

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The gap between the top of the valence
band and bottom of the conduction band
is called the energy band gap (Energy gap

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Eg ). It may be large, small, or zero,
depending upon the material. These
different situations, are depicted in Fig.
14.2 and discussed below:

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Case I: This refers to a situation, as

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shown in Fig. 14.2(a). One can have a
metal either when the conduction band
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is partially filled and the balanced band FIGURE 14.1 The energy band positions in a

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is partially empty or when the conduction semiconductor at 0 K. The upper band, called the
and valance bands overlap. When there conduction band, consists of infinitely large number
E
of closely spaced energy states. The lower band,
is overlap electrons from valence band can
called the valence band, consists of closely spaced
easily move into the conduction band.
completely filled energy states.
This situation makes a large number of
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electrons available for electrical conduction. When the valence band is
partially empty, electrons from its lower level can move to higher level
making conduction possible. Therefore, the resistance of such materials
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is low or the conductivity is high.
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FIGURE 14.2 Difference between energy bands of (a) metals,
(b) insulators and (c) semiconductors. 471
 Physics
Case II: In this case, as shown in Fig. 14.2(b), a large band gap Eg exists
(Eg > 3 eV). There are no electrons in the conduction band, and therefore
no electrical conduction is possible. Note that the energy gap is so large
that electrons cannot be excited from the valence band to the conduction
band by thermal excitation. This is the case of insulators.
Case III: This situation is shown in Fig. 14.2(c). Here a finite but small

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band gap (E g < 3 eV) exists. Because of the small band gap, at room
temperature some electrons from valence band can acquire enough

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energy to cross the energy gap and enter the conduction band. These
electrons (though small in numbers) can move in the conduction band.
Hence, the resistance of semiconductors is not as high as that of the
insulators.
In this section we have made a broad classification of metals,

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conductors and semiconductors. In the section which follows you will
learn the conduction process in semiconductors.
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14.3 INTRINSIC SEMICONDUCTOR
We shall take the most common case of Ge and Si whose lattice structure
E
is shown in Fig. 14.3. These structures are called the diamond-like
structures. Each atom is surrounded by four nearest neighbours. We
know that Si and Ge have four valence electrons. In its crystalline
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structure, every Si or Ge atom tends to share one of its four valence
electrons with each of its four nearest neighbour atoms, and also to take
share of one electron from each such neighbour. These shared electron
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pairs are referred to as forming a covalent bond or simply a valence
bond. The two shared electrons can be assumed to shuttle back-and-
forth between the associated atoms holding them together strongly.
Figure 14.4 schematically shows the 2-dimensional representation of Si
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or Ge structure shown in Fig. 14.3 which overemphasises the covalent
bond. It shows an idealised picture in which no bonds are broken (all
bonds are intact). Such a situation arises at low
temperatures. As the temperature increases, more
thermal energy becomes available to these electrons
and some of these electrons may break–away
(becoming free electrons contributing to conduction).
The thermal energy effectively ionises only a few atoms
in the crystalline lattice and creates a vacancy in the
bond as shown in Fig. 14.5(a). The neighbourhood,
from which the free electron (with charge –q ) has come
out leaves a vacancy with an effective charge (+q ). This
vacancy with the effective positive electronic charge is
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called a hole. The hole behaves as an apparent free
particle with effective positive charge.
FIGURE 14.3 Three-dimensional dia-
In intrinsic semiconductors, the number of free
mond-like crystal structure for Carbon, electrons, ne is equal to the number of holes, n h. That is
Silicon or Germanium with n e
= n h
= ni (14.1)
respective lattice spacing a equal where n i is called intrinsic carrier concentration.
to 3.56, 5.43 and 5.66 Å. Semiconductors posses the unique property in
472 which, apart from electrons, the holes also move.
 Semiconductor Electronics:
Materials, Devices and
Simple Circuits
Suppose there is a hole at site 1 as shown in
Fig. 14.5(a). The movement of holes can be
visualised as shown in Fig. 14.5(b). An electron
from the covalent bond at site 2 may jump to
the vacant site 1 (hole). Thus, after such a jump,
the hole is at site 2 and the site 1 has now an

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electron. Therefore, apparently, the hole has
moved from site 1 to site 2. Note that the electron
originally set free [Fig. 14.5(a)] is not involved

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in this process of hole motion. The free electron
moves completely independently as conduction
electron and gives rise to an electron current, I e
under an applied electric field. Remember that

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the motion of hole is only a convenient way of

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FIGURE 14.4 Schematic two-dimensional
describing the actual motion of bound electrons, representation of Si or Ge structure showing
whenever there is an empty bond anywhere in covalent bonds at low temperature
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the crystal. Under the action of an electric field, (all bonds intact). +4 symbol

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these holes move towards negative potential indicates inner cores of Si or Ge.
giving the hole current, Ih. The total current, I is
E
thus the sum of the electron current I e and the
hole current Ih:
I = Ie + Ih (14.2)
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It may be noted that apart from the process of generation of conduction
electrons and holes, a simultaneous process of recombination occurs in
which the electrons recombine with the holes. At equilibrium, the rate of
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generation is equal to the rate of recombination of charge carriers. The
recombination occurs due to an electron colliding with a hole.
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(a) (b)
FIGURE 14.5 (a) Schematic model of generation of hole at site 1 and conduction electron
due to thermal energy at moderate temperatures. (b) Simplified representation of
possible thermal motion of a hole. The electron from the lower left hand covalent bond
(site 2) goes to the earlier hole site1, leaving a hole at its site indicating an
apparent movement of the hole from site 1 to site 2. 473
 Physics
An intrinsic semiconductor
will behave like an insulator at
T = 0 K as shown in Fig. 14.6(a).
It is the thermal energy at
higher temperatures (T > 0K),
which excites some electrons
from the valence band to the

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conduction band. These
thermally excited electrons at

he
T > 0 K, partially occupy the
conduction band. Therefore,
the energy-band diagram of an
intrinsic semiconductor will be
FIGURE 14.6 (a) An intrinsic semiconductor at T = 0 K as shown in Fig. 14.6(b). Here,

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behaves like insulator. (b) At T > 0 K, four ther mally generated some electrons are shown in
electron-hole pairs. The filled circles ( ) represent electrons the conduction band. These
and empty fields ( ) represent holes. have come from the valence
re R band leaving equal number of

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holes there.
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Example 14.1 C, Si and Ge have same lattice structure. Why is C
insulator while Si and Ge intrinsic semiconductors?
EXAMPLE 14.1

be C

Solution The 4 bonding electrons of C, Si or Ge lie, respectively, in
the second, third and fourth orbit. Hence, energy required to take
out an electron from these atoms (i.e., ionisation energy Eg ) will be
least for Ge, followed by Si and highest for C. Hence, number of free
o N

electrons for conduction in Ge and Si are significant but negligibly
small for C.
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14.4 EXTRINSIC SEMICONDUCTOR
The conductivity of an intrinsic semiconductor depends on its
temperature, but at room temperature its conductivity is very low. As
such, no important electronic devices can be developed using these
semiconductors. Hence there is a necessity of improving their
conductivity. This can be done by making use of impurities.
When a small amount, say, a few parts per million (ppm), of a suitable
impurity is added to the pure semiconductor, the conductivity of the
semiconductor is increased manifold. Such materials are known as
extrinsic semiconductors or impurity semiconductors. The deliberate
addition of a desirable impurity is called doping and the impurity atoms
are called dopants. Such a material is also called a doped semiconductor.
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The dopant has to be such that it does not distort the original pure
semiconductor lattice. It occupies only a very few of the original
semiconductor atom sites in the crystal. A necessary condition to attain
this is that the sizes of the dopant and the semiconductor atoms should
be nearly the same.
There are two types of dopants used in doping the tetravalent Si
or Ge:
(i) Pentavalent (valency 5); like Arsenic (As), Antimony (Sb), Phosphorous
474 (P), etc.
 Semiconductor Electronics:
Materials, Devices and
Simple Circuits
(ii) Trivalent (valency 3); like Indium (In),
Boron (B), Aluminium (Al), etc.
We shall now discuss how the doping
changes the number of charge carriers (and
hence the conductivity) of semiconductors.
Si or Ge belongs to the fourth group in the

d
Periodic table and, therefore, we choose the
dopant element from nearby fifth or third
group, expecting and taking care that the

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size of the dopant atom is nearly the same as
that of Si or Ge. Interestingly, the pentavalent
and trivalent dopants in Si or Ge give two
entirely different types of semiconductors as

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discussed below.
(i) n-type semiconductor
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Suppose we dope Si or Ge with a pentavalent
element as shown in Fig. 14.7. When an atom
of +5 valency element occupies the position
E
of an atom in the crystal lattice of Si, four of
its electrons bond with the four silicon
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neighbours while the fifth remains very
weakly bound to its parent atom. This is
because the four electrons participating in
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bonding are seen as part of the effective core FIGURE 14.7 (a) Pentavalent donor atom (As, Sb,
of the atom by the fifth electron. As a result P, etc.) doped for tetravalent Si or Ge giving n-
the ionisation energy required to set this type semiconductor, and (b) Commonly used
schematic representation of n-type material
electron free is very small and even at room
which shows only the fixed cores of the
temperature it will be free to move in the
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substituent donors with one additional effective
lattice of the semiconductor. For example, the positive charge and its associated extra electron.
energy required is ~ 0.01 eV for germanium,
and 0.05 eV for silicon, to separate this
electron from its atom. This is in contrast to the energy required to jump
the forbidden band (about 0.72 eV for germanium and about 1.1 eV for
silicon) at room temperature in the intrinsic semiconductor. Thus, the
pentavalent dopant is donating one extra electron for conduction and
hence is known as donor impurity. The number of electrons made
available for conduction by dopant atoms depends strongly upon the
doping level and is independent of any increase in ambient temperature.
On the other hand, the number of free electrons (with an equal number
of holes) generated by Si atoms, increases weakly with temperature.
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In a doped semiconductor the total number of conduction electrons
ne is due to the electrons contributed by donors and those generated
intrinsically, while the total number of holes n h is only due to the holes
from the intrinsic source. But the rate of recombination of holes would
increase due to the increase in the number of electrons. As a result, the
number of holes would get reduced further.
Thus, with proper level of doping the number of conduction electrons
can be made much larger than the number of holes. Hence in an extrinsic 475
 Physics
semiconductor doped with pentavalent impurity, electrons
become the majority carriers and holes the minority carriers.
These semiconductors are, therefore, known as n-type
semiconductors. For n-type semiconductors, we have,
ne >> nh (14.3)
(ii) p-type semiconductor

d
This is obtained when Si or Ge is doped with a trivalent impurity
like Al, B, In, etc. The dopant has one valence electron less than

he
Si or Ge and, therefore, this atom can form covalent bonds with
neighbouring three Si atoms but does not have any electron to
offer to the fourth Si atom. So the bond between the fourth
neighbour and the trivalent atom has a vacancy or hole as shown

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in Fig. 14.8. Since the neighbouring Si atom in the lattice wants

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an electron in place of a hole, an electron in the outer orbit of
an atom in the neighbourhood may jump to fill this vacancy,
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available for conduction. Note that the trivalent foreign atom
becomes effectively negatively charged when it shares fourth
E
electron with neighbouring Si atom. Therefore, the dopant atom
of p-type material can be treated as core of one negative charge
along with its associated hole as shown in Fig. 14.8(b). It is
be C

obvious that one acceptor atom gives one hole. These holes are
in addition to the intrinsically generated holes while the source
of conduction electrons is only intrinsic generation. Thus, for
o N

such a material, the holes are the majority carriers and electrons
FIGURE 14.8 (a) Trivalent are minority carriers. Therefore, extrinsic semiconductors doped
acceptor atom (In, Al, B etc.) with trivalent impurity are called p-type semiconductors. For
doped in tetravalent Si or Ge
p-type semiconductors, the recombination process will reduce
lattice giving p-type semicon-
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ductor. (b) Commonly used
the number (n i)of intrinsically generated electrons to ne. We
schematic representation of have, for p-type semiconductors
p-type material which shows nh >> ne (14.4)
only the fixed core of the Note that the crystal maintains an overall charge neutrality
substituent acceptor with
as the charge of additional charge carriers is just equal and
one effective additional
negative charge and its
opposite to that of the ionised cores in the lattice.
associated hole. In extrinsic semiconductors, because of the abundance of
majority current carriers, the minority carriers produced
thermally have more chance of meeting majority carriers and
thus getting destroyed. Hence, the dopant, by adding a large number of
current carriers of one type, which become the majority carriers, indirectly
helps to reduce the intrinsic concentration of minority carriers.
The semiconductor’s energy band structure is affected by doping. In
no

the case of extrinsic semiconductors, additional energy states due to donor
impurities (ED ) and acceptor impurities (EA ) also exist. In the energy band
diagram of n-type Si semiconductor, the donor energy level ED is slightly
below the bottom EC of the conduction band and electrons from this level
move into the conduction band with very small supply of energy. At room
temperature, most of the donor atoms get ionised but very few (~10–12)
atoms of Si get ionised. So the conduction band will have most electrons
476 coming from the donor impurities, as shown in Fig. 14.9(a). Similarly,
 Semiconductor Electronics:
Materials, Devices and
Simple Circuits
for p-type semiconductor, the acceptor energy level EA is slightly above
the top EV of the valence band as shown in Fig. 14.9(b). With very small
supply of energy an electron from the valence band can jump to the level
EA and ionise the acceptor negatively. (Alternately, we can also say that
with very small supply of energy the hole from level EA sinks down into
the valence band. Electrons rise up and holes fall down when they gain

d
external energy.) At room temperature, most of the acceptor atoms get
ionised leaving holes in the valence band. Thus at room temperature the
density of holes in the valence band is predominantly due to impurity in

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the extrinsic semiconductor. The electron and hole concentration in a
semiconductor in thermal equilibrium is given by
ne nh = n i2 (14.5)

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Though the above description is grossly approximate and

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hypothetical, it helps in understanding the difference between metals,
insulators and semiconductors (extrinsic and intrinsic) in a simple
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manner. The difference in the resistivity of C, Si and Ge depends upon

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the energy gap between their conduction and valence bands. For C
(diamond), Si and Ge, the energy gaps are 5.4 eV, 1.1 eV and 0.7 eV,
E
respectively. Sn also is a group IV element but it is a metal because the
energy gap in its case is 0 eV.
be C
o N
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FIGURE 14.9 Energy bands of (a) n-type semiconductor at T > 0K, (b) p-type
semiconductor at T > 0K.

Example 14.2 Suppose a pure Si crystal has 5 × 1028 atoms m–3. It is
doped by 1 ppm concentration of pentavalent As. Calculate the
no

number of electrons and holes. Given that ni =1.5 × 10 16 m–3.
Solution Note that thermally generated electrons (ni ~10 16 m–3 ) are
EXAMPLE 14.2

negligibly small as compared to those produced by doping.
Therefore, ne ≈ ND.
2
Since nenh = ni , The number of holes
nh = (2.25 × 1032)/(5 ×1022)
~ 4.5 × 109 m–3
477
 Physics
14.5 p-n JUNCTION
A p-n junction is the basic building block of many semiconductor devices
like diodes, transistor, etc. A clear understanding of the junction behaviour
is important to analyse the working of other semiconductor devices.
We will now try to understand how a junction is formed and how the

d
junction behaves under the influence of external applied voltage (also
called bias).
http://hyperphysics.phy-astr.gsu.edu/hbase/solids/pnjun.html

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14.5.1 p-n junction formation
Consider a thin p-type silicon (p-Si) semiconductor wafer. By adding
precisely a small quantity of pentavelent impurity, part of the p-Si wafer
can be converted into n-Si. There are several processes by which a

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semiconductor can be formed. The wafer now contains p-region and
Formation and working of p-n junction diode

n-region and a metallurgical junction between p-, and n- region.
re R Two important processes occur during the formation of a p-n junction:

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diffusion and drift. We know that in an n-type semiconductor, the
concentration of electrons (number of electrons per unit volume) is more
E
compared to the concentration of holes. Similarly, in a p-type
semiconductor, the concentration of holes is more than the concentration
of electrons. During the formation of p-n junction, and due to the
be C

concentration gradient across p-, and n- sides, holes diffuse from p-side
to n-side (p → n) and electrons diffuse from n-side to p-side (n → p). This
motion of charge carries gives rise to diffusion current across the junction.
o N

When an electron diffuses from n → p, it leaves behind an ionised
donor on n-side. This ionised donor (positive charge) is immobile as it is
bonded to the surrounding atoms. As the electrons continue to diffuse
from n → p, a layer of positive charge (or positive space-charge region) on
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n-side of the junction is developed.
Similarly, when a hole diffuses from p → n due to the concentration
gradient, it leaves behind an ionised acceptor (negative charge) which is
immobile. As the holes continue to diffuse, a layer of negative charge (or
negative space-charge region) on the p-side of the junction is developed.
This space-charge region on either side of the junction together is known
as depletion region as the electrons and holes taking part in the initial
movement across the junction depleted the region of its
free charges (Fig. 14.10). The thickness of depletion region
is of the order of one-tenth of a micrometre. Due to the
positive space-charge region on n-side of the junction and
no

negative space charge region on p-side of the junction,
an electric field directed from positive charge towards
negative charge develops. Due to this field, an electron on
p-side of the junction moves to n-side and a hole on n-
side of the junction moves to p-side. The motion of charge
FIGURE 14.10 p-n junction carriers due to the electric field is called drift. Thus a
formation process. drift current, which is opposite in direction to the diffusion
478 current (Fig. 14.10) starts.
 Semiconductor Electronics:
Materials, Devices and
Simple Circuits
Initially, diffusion current is large and drift current is small.
As the diffusion process continues, the space-charge regions
on either side of the junction extend, thus increasing the electric
field strength and hence drift current. This process continues
until the diffusion current equals the drift current. Thus a p-n
junction is formed. In a p-n junction under equilibrium there

d
is no net current.
The loss of electrons from the n-region and the gain of
electron by the p-region causes a difference of potential across

he
the junction of the two regions. The polarity of this potential is
such as to oppose further flow of carriers so that a condition of
equilibrium exists. Figure 14.11 shows the p-n junction at
equilibrium and the potential across the junction. The

pu T
is
n-material has lost electrons, and p material has acquired
electrons. The n material is thus positive relative to the p
re R
material. Since this potential tends to prevent the movement of FIGURE 14.11 (a) Diode under

bl
electron from the n region into the p region, it is often called a equilibrium (V = 0), (b) Barrier
barrier potential. potential under no bias.
E
Example 14.3 Can we take one slab of p-type semiconductor and

EXAMPLE 14.3
physically join it to another n-type semiconductor to get p-n junction?
be C

Solution No! Any slab, howsoever flat, will have roughness much
larger than the inter-atomic crystal spacing (~2 to 3 Å) and hence
continuous contact at the atomic level will not be possible. The junction
o N

will behave as a discontinuity for the flowing charge carriers.

14.6 SEMICONDUCTOR DIODE
tt ©

A semiconductor diode [Fig. 14.12(a)] is basically a
p-n junction with metallic contacts provided at the
ends for the application of an external voltage. It is a
two terminal device. A p-n junction diode is
symbolically represented as shown in Fig. 14.12(b).
The direction of arrow indicates the conventional
direction of current (when the diode is under forward
bias). The equilibrium barrier potential can be altered
by applying an external voltage V across the diode.
The situation of p-n junction diode under equilibrium FIGURE 14.12 (a) Semiconductor diode,
(without bias) is shown in Fig. 14.11(a) and (b). (b) Symbol for p-n junction diode.

14.6.1 p-n junction diode under forward bias
no

When an external voltage V is applied across a semiconductor diode such
that p-side is connected to the positive terminal of the battery and n-side
to the negative terminal [Fig. 14.13(a)], it is said to be forward biased.
The applied voltage mostly drops across the depletion region and the
voltage drop across the p-side and n-side of the junction is negligible.
(This is because the resistance of the depletion region – a region where
there are no charges – is very high compared to the resistance of n-side
and p-side.) The direction of the applied voltage (V ) is opposite to the 479
 Physics
built-in potential V0. As a result, the depletion layer width
decreases and the barrier height is reduced [Fig. 14.13(b)]. The
effective barrier height under forward bias is (V 0 – V ).
If the applied voltage is small, the barrier potential will be
reduced only slightly below the equilibrium value, and only a
small number of carriers in the material—those that happen to

d
be in the uppermost energy levels—will possess enough energy
to cross the junction. So the current will be small. If we increase
the applied voltage significantly, the barrier height will be reduced

he
and more number of carriers will have the required energy. Thus
the current increases.
Due to the applied voltage, electrons from n-side cross the
depletion region and reach p-side (where they are minority

pu T
carries). Similarly, holes from p-side cross the junction and reach

is
the n-side (where they are minority carries). This process under
forward bias is known as minority carrier injection. At the
FIGURE 14.13 (a) p-n
re R
junction diode under forward
junction boundary, on each side, the minority carrier

bl
bias, (b) Barrier potential
concentration increases significantly compared to the locations
(1) without battery, (2) Low far from the junction.
E
battery voltage, and (3) High Due to this concentration gradient, the injected electrons on
voltage battery. p-side diffuse from the junction edge of p-side to the other end
of p-side. Likewise, the injected holes on n-side diffuse from the
be C

junction edge of n-side to the other end of n-side
(Fig. 14.14). This motion of charged carriers on either side
gives rise to current. The total diode forward current is sum
of hole diffusion current and conventional current due to
o N

electron diffusion. The magnitude of this current is usually
in mA.

14.6.2 p-n junction diode under reverse bias
tt ©

FIGURE 14.14 Forward bias When an external voltage (V ) is applied across the diode such
minority carrier injection. that n-side is positive and p-side is negative, it is said to be
reverse biased [Fig.14.15(a)]. The applied voltage mostly
drops across the depletion region. The direction of applied voltage is same
as the direction of barrier potential. As a result, the barrier height increases
and the depletion region widens due to the change in the electric field.
The effective barrier height under reverse bias is (V0 + V ), [Fig. 14.15(b)].
This suppresses the flow of electrons from n → p and holes from p → n.
Thus, diffusion current, decreases enormously compared to the diode
under forward bias.
The electric field direction of the junction is such that if electrons on
p-side or holes on n-side in their random motion come close to the
junction, they will be swept to its majority zone. This drift of carriers
no

gives rise to current. The drift current is of the order of a few µA. This is
quite low because it is due to the motion of carriers from their minority
side to their majority side across the junction. The drift current is also
there under forward bias but it is negligible (µA) when compared with
current due to injected carriers which is usually in mA.
The diode reverse current is not very much dependent on the applied
voltage. Even a small voltage is sufficient to sweep the minority carriers
480 from one side of the junction to the other side of the junction. The current
 Semiconductor Electronics:
Materials, Devices and
Simple Circuits
is not limited by the magnitude of the applied voltage but is
limited due to the concentration of the minority carrier on either
side of the junction.
The current under reverse bias is essentially voltage
independent upto a critical reverse bias voltage, known as
breakdown voltage (Vbr ). When V = Vbr, the diode reverse current

d
increases sharply. Even a slight increase in the bias voltage causes
large change in the current. If the reverse current is not limited by

he
an external circuit below the rated value (specified by the
manufacturer) the p-n junction will get destroyed. Once it exceeds
the rated value, the diode gets destroyed due to overheating. This
can happen even for the diode under forward bias, if the forward
current exceeds the rated value.

pu T
is
The circuit arrangement for studying the V-I characteristics
of a diode, (i.e., the variation of current as a function of applied FIGURE 14.15 (a) Diode
re R
voltage) are shown in Fig. 14.16(a) and (b). The battery is connected under reverse bias,

bl
to the diode through a potentiometer (or reheostat) so that the (b) Barrier potential under
applied voltage to the diode can be changed. For different values reverse bias.
E
of voltages, the value of the current is noted. A graph between V
and I is obtained as in Fig. 14.16(c). Note that in forward bias
measurement, we use a milliammeter since the expected current is large
be C

(as explained in the earlier section) while a micrometer is used in reverse
bias to measure the current. You can see in Fig. 14.16(c) that in forward
o N
tt ©
no

FIGURE 14.16 Experimental circuit arrangement for studying V-I characteristics of
a p-n junction diode (a) in forward bias , (b) in reverse bias. (c) Typical V-I
characteristics of a silicon diode. 481
 Physics
bias, the current first increases very slowly, almost negligibly, till the
voltage across the diode crosses a certain value. After the characteristic
voltage, the diode current increases significantly (exponentially), even for
a very small increase in the diode bias voltage. This voltage is called the
threshold voltage or cut-in voltage (~0.2V for germanium diode and
~0.7 V for silicon diode).

d
For the diode in reverse bias, the current is very small (~µA) and almost
remains constant with change in bias. It is called reverse saturation
current. However, for special cases, at very high reverse bias (break down

he
voltage), the current suddenly increases. This special action of the diode
is discussed later in Section 14.8. The general purpose diode are not
used beyond the reverse saturation current region.
The above discussion shows that the p-n junction diode primerly

pu T
is
allows the flow of current only in one direction (forward bias). The forward
bias resistance is low as compared to the reverse bias resistance. This
re R property is used for rectification of ac voltages as discussed in the next

bl
section. For diodes, we define a quantity called dynamic resistance as
the ratio of small change in voltage ∆V to a small change in current ∆I:
E
∆V
rd = (14.6)
∆I
be C

Example 14.4 The V-I characteristic of a silicon diode is shown in
the Fig. 14.17. Calculate the resistance of the diode at (a) I D = 15 mA
and (b) VD = –10 V.
o N
tt ©

FIGURE 14.17
no

Solution Considering the diode characteristics as a straight line
between I = 10 mA to I = 20 mA passing through the origin, we can
EXAMPLE 14.4

calculate the resistance using Ohm’s law.
(a) From the curve, at I = 20 mA, V = 0.8 V, I = 10 mA, V = 0.7 V
rf b = ∆V/∆I = 0.1V/10 mA = 10 Ω
(b) From the curve at V = –10 V, I = –1 µA,
Therefore,
rrb = 10 V/1µA= 1.0 × 107 Ω
482
 Semiconductor Electronics:
Materials, Devices and
Simple Circuits

14.7 APPLICATION OF JUNCTION DIODE AS A RECTIFIER
From the V-I characteristic of a junction diode we see that it allows current
to pass only when it is forward biased. So if an alternating voltage is
applied across a diode the current flows only in that part of the cycle
when the diode is forward biased. This property

d
is used to rectify alternating voltages and the
circuit used for this purpose is called a rectifier.
If an alternating voltage is applied across a

he
diode in series with a load, a pulsating voltage will
appear across the load only during the half cycles
of the ac input during which the diode is forward
biased. Such rectifier circuit, as shown in

pu T
is
Fig. 14.18, is called a half-wave rectifier. The
secondary of a transformer supplies the desired
ac voltage across terminals A and B. When the
re R
voltage at A is positive, the diode is forward biased

bl
and it conducts. When A is negative, the diode is
reverse-biased and it does not conduct. The reverse
E
saturation current of a diode is negligible and can
be considered equal to zero for practical purposes.
(The reverse breakdown voltage of the diode must
be C

be sufficiently higher than the peak ac voltage at
the secondary of the transformer to protect the
diode from reverse breakdown.)
o N

Therefore, in the positive half-cycle of ac there
is a current through the load resistor R L and we FIGURE 14.18 (a) Half-wave rectifier
circuit, (b) Input ac voltage and output
get an output voltage, as shown in Fig. 14.18(b),
voltage waveforms from the rectifier circuit.
whereas there is no current in the negative half-
tt ©

cycle. In the next positive half-cycle, again we get
the output voltage. Thus, the output voltage, though still varying, is
restricted to only one direction and is said to be rectified. Since the
rectified output of this circuit is only for half of the input ac wave it is
called as half-wave rectifier.
The circuit using two diodes, shown in Fig. 14.19(a), gives output
rectified voltage corresponding to both the positive as well as negative
half of the ac cycle. Hence, it is known as full-wave rectifier. Here the
p-side of the two diodes are connected to the ends of the secondary of the
transformer. The n-side of the diodes are connected together and the
output is taken between this common point of diodes and the midpoint
of the secondary of the transformer. So for a full-wave rectifier the
no

secondary of the transformer is provided with a centre tapping and so it
is called centre-tap transformer. As can be seen from Fig.14.19(c) the
voltage rectified by each diode is only half the total secondary voltage.
Each diode rectifies only for half the cycle, but the two do so for alternate
cycles. Thus, the output between their common terminals and the centre-
tap of the transformer becomes a full-wave rectifier output. (Note that
there is another circuit of full wave rectifier which does not need a centre-
tap transformer but needs four diodes.) Suppose the input voltage to A 483
 Physics
with respect to the centre tap at any instant
is positive. It is clear that, at that instant,
voltage at B being out of phase will be
negative as shown in Fig.14.19(b). So, diode
D1 gets forward biased and conducts (while
D2 being reverse biased is not conducting).

d
Hence, during this positive half cycle we get
an output current (and a output voltage

he
across the load resistor R L) as shown in
Fig.14.19(c). In the course of the ac cycle
when the voltage at A becomes negative with
respect to centre tap, the voltage at B would
be positive. In this part of the cycle diode

pu T
is
D1 would not conduct but diode D2 would,
giving an output current and output
re R voltage (across RL ) during the negative half

bl
cycle of the input ac. Thus, we get output
voltage during both the positive as well as
E
the negative half of the cycle. Obviously,
this is a more efficient circuit for getting
rectified voltage or current than the half-
be C

wave rectifier
The rectified voltage is in the form of
pulses of the shape of half sinusoids.
o N

Though it is unidirectional it does not have
a steady value. To get steady dc output
from the pulsating voltage normally a
capacitor is connected across the output
tt ©

terminals (parallel to the load RL). One can
also use an inductor in series with RL for
FIGURE 14.19 (a) A Full-wave rectifier the same purpose. Since these additional
circuit; (b) Input wave forms given to the
circuits appear to filter out the ac ripple
diode D 1 at A and to the diode D2 at B;
(c) Output waveform across the
and give a pure dc voltage, so they are
load RL connected in the full-wave called filters.
rectifier circuit. Now we shall discuss the role of
capacitor in filtering. When the voltage
across the capacitor is rising, it gets
charged. If there is no external load, it remains charged to the peak voltage
of the rectified output. When there is a load, it gets discharged through
the load and the voltage across it begins to fall. In the next half-cycle of
no

rectified output it again gets charged to the peak value (Fig. 14.20). The
rate of fall of the voltage across the capacitor depends upon the inverse
product of capacitor C and the effective resistance R L used in the circuit
and is called the time constant. To make the time constant large value of
C should be large. So capacitor input filters use large capacitors. The
output voltage obtained by using capacitor input filter is nearer to the
peak voltage of the rectified voltage. This type of filter is most widely
484 used in power supplies.
 Semiconductor Electronics:
Materials, Devices and
Simple Circuits

d
he
FIGURE 14.20 (a) A full-wave rectifier with capacitor filter, (b) Input and output
voltage of rectifier in (a).

pu T
14.8 SPECIAL PURPOSE p-n JUNCTION DIODES

is
In the section, we shall discuss some devices which are basically junction
re R
diodes but are developed for different applications.

bl
14.8.1 Zener diode
E
It is a special purpose semiconductor diode, named after its inventor
C. Zener. It is designed to operate under reverse bias in the breakdown
region and used as a voltage regulator. The symbol for Zener diode is
be C

shown in Fig. 14.21(a).
Zener diode is fabricated by heavily doping both p-, and
n- sides of the junction. Due to this, depletion region formed
o N

is very thin ( I3 > I2 > I1.
tt ©

Example 14.6 The current in the forward bias is known to be more
(~mA) than the current in the reverse bias (~µA). What is the reason
then to operate the photodiodes in reverse bias?
Solution Consider the case of an n-type semiconductor. Obviously,
the majority carrier density (n ) is considerably larger than the
minority hole density p (i.e., n >> p). On illumination, let the excess
electrons and holes generated be ∆n and ∆p, respectively:
EXAMPLE 14.6

n′ = n + ∆n
p ′ = p + ∆p
Here n′ and p ′ are the electron and hole concentrations* at any
no

particular illumination and n and p are carriers concentration when
there is no illumination. Remember ∆n = ∆p and n >> p. Hence, the

* Note that, to create an e-h pair, we spend some ener gy (photoexcitation, thermal
excitation, etc.). Therefore when an electron and hole recombine the energy is
released in the form of light (radiative recombination) or heat (non-radiative
recombination). It depends on semiconductor and the method of fabrication of
the p-n junction. For the fabrication of LEDs, semiconductors like GaAs, GaAs-
GaP are used in which radiative recombination dominates. 487
 Physics
EXAMPLE 14.6 fractional change in the majority carriers (i.e., ∆n/n ) would be much
less than that in the minority carriers (i.e., ∆p/p). In general, we can
state that the fractional change due to the photo-effects on the
minority carrier dominated reverse bias current is more easily
measurable than the fractional change in the forward bias current.
Hence, photodiodes are preferably used in the reverse bias condition

d
for measuring light intensity.

he
(ii) Light emitting diode
It is a heavily doped p-n junction which under forward bias emits
spontaneous radiation. The diode is encapsulated with a transparent
cover so that emitted light can come out.

pu T
is
When the diode is forward biased, electrons are sent from n → p (where
they are minority carriers) and holes are sent from p → n (where they are
re R minority carriers). At the junction boundary the concentration of minority

bl
carriers increases compared to the equilibrium concentration (i.e., when
there is no bias). Thus at the junction boundary on either side of the
junction, excess minority carriers are there which recombine with majority
E
carriers near the junction. On recombination, the energy is released in
the form of photons. Photons with energy equal to or slightly less than
be C

the band gap are emitted. When the forward current of the diode is small,
the intensity of light emitted is small. As the forward current increases,
intensity of light increases and reaches a maximum. Further increase in
o N

the forward current results in decrease of light intensity. LEDs are biased
such that the light emitting efficiency is maximum.
The V-I characteristics of a LED is similar to that of a Si junction
diode. But the threshold voltages are much higher and slightly different
for each colour. The reverse breakdown voltages of LEDs are very low,
tt ©

typically around 5V. So care should be taken that high reverse voltages
do not appear across them.
LEDs that can emit red, yellow, orange, green and blue light are
commercially available. The semiconductor used for fabrication of visible
LEDs must at least have a band gap of 1.8 eV (spectral range of visible
light is from about 0.4 µm to 0.7 µm, i.e., from about 3 eV to 1.8 eV). The
compound semiconductor Gallium Arsenide – Phosphide (GaAs 1–x P x ) is
used for making LEDs of different colours. GaAs0.6 P0.4 (Eg ~ 1.9 eV) is
used for red LED. GaAs (E g ~ 1.4 eV) is used for making infrared LED.
These LEDs find extensive use in remote controls, burglar alarm systems,
optical communication, etc. Extensive research is being done for
developing white LEDs which can replace incandescent lamps.
no

LEDs have the following advantages over conventional incandescent
low power lamps:
(i) Low operational voltage and less power.
(ii) Fast action and no warm-up time required.
(iii) The bandwidth of emitted light is 100 Å to 500 Å or in other words it
is nearly (but not exactly) monochromatic.
(iv) Long life and ruggedness.
488 (v) Fast on-off switching capability.
 Semiconductor Electronics:
Materials, Devices and
Simple Circuits
(iii) Solar cell
A solar cell is basically a p-n junction which
generates emf when solar radiation falls on the
p-n junction. It works on the same principle
(photovoltaic effect) as the photodiode, except that
no external bias is applied and the junction area

d
is kept much larger for solar radiation to be
incident because we are interested in more power.
A simple p-n junction solar cell is shown in

he
Fig. 14.24.
A p-Si wafer of about 300 µm is taken over
which a thin layer (~0.3 µm) of n-Si is grown on
one-side by diffusion process. The other side of

pu T
p-Si is coated with a metal (back contact). On the

is
top of n-Si layer, metal finger electrode (or metallic
grid) is deposited. This acts as a front contact. The FIGURE 14.24 (a) Typical p-n junction
re R
metallic grid occupies only a very small fraction solar cell; (b) Cross-sectional view.

bl
of the cell area ( Eg )
be C

close to the junction; (ii) separation of electrons and
holes due to electric field of the depletion region.
Electrons are swept to n-side and holes to p-side;
(iii) the electrons reaching the n-side are collected by
o N

the front contact and holes reaching p-side are collected
by the back contact. Thus p-side becomes positive and
n-side becomes negative giving rise to photovoltage.
When an external load is connected as shown in
tt ©

the Fig. 14.25(a) a photocurrent IL flows through the
load. A typical I-V characteristics of a solar cell is shown
in the Fig. 14.25(b).
Note that the I – V characteristics of solar cell is
drawn in the fourth quadrant of the coordinate axes.
This is because a solar cell does not draw current but
supplies the same to the load.
Semiconductors with band gap close to 1.5 eV are
ideal materials for solar cell fabrication. Solar cells are
made with semiconductors like Si (Eg = 1.1 eV), GaAs
(Eg = 1.43 eV), CdTe (Eg = 1.45 eV), CuInSe2 (Eg = 1.04
eV), etc. The important criteria for the selection of a
material for solar cell fabrication are (i) band gap (~1.0
to 1.8 eV), (ii) high optical absorption (~104 cm –1), (iii)
no

electrical conductivity, (iv) availability of the raw
material, and (v) cost. Note that sunlight is not always FIGURE 14.25 (a) A typical
required for a solar cell. Any light with photon energies illuminated p-n junction solar cell;
(b) I-V characteristics of a solar cell.
greater than the bandgap will do. Solar cells are used
to power electronic devices in satellites and space
vehicles and also as power supply to some calculators. Production of
low-cost photovoltaic cells for large-scale solar energy is a topic
for research. 489
 Physics
Example 14.7 Why are Si and GaAs are preferred materials for
solar cells?
Solution The solar radiation spectrum received by us is shown in
Fig. 14.26.

d
he
pu T
is
re R
bl
E
be C

FIGURE 14.26

The maxima is near 1.5 eV. For photo-excitation, hν > Eg. Hence,
o N

semiconductor with band gap ~1.5 eV or lower is likely to give better
solar conversion efficiency. Silicon has Eg ~ 1.1 eV while for GaAs it is
~1.53 eV. In fact, GaAs is better (in spite of its higher band gap) than
Si because of its relatively higher absorption coefficient. If we choose
materials like CdS or CdSe (E g ~ 2.4 eV), we can use only the high
tt ©

energy component of the solar energy for photo-conversion and a
significant part of energy will be of no use.
The question arises: why we do not use material like PbS (Eg ~ 0.4 eV)
EXAMPLE 14.7

which satisfy the condition hν > Eg for ν maxima corresponding to the
solar radiation spectra? If we do so, most of the solar radiation will be
absorbed on the top-layer of solar cell and will not reach in or near
the depletion region. For effective electron-hole separation, due to
the junction field, we want the photo-generation to occur in the
junction region only.

14.9 J UNCTION TRANSISTOR
The credit of inventing the transistor in the year 1947 goes to J. Bardeen
no

and W.H. Brattain of Bell Telephone Laboratories, U.S.A. That transistor
was a point-contact transistor. The first junction transistor consisting of
two back-to-back p-n junctions was invented by William Schockley
in 1951.
As long as only the junction transistor was known, it was known
simply as transistor. But over the years new types of transistors were
invented and to differentiate it from the new ones it is now called the
490 Bipolar Junction Transistor (BJT). Even now, often the word transistor
 Semiconductor Electronics:
Materials, Devices and
Simple Circuits
is used to mean BJT when there is no confusion. Since our study is
limited to only BJT, we shall use the word transistor for BJT without
any ambiguity.

14.9.1 Transistor: structure and action
A transistor has three doped regions forming two p-n junctions

d
between them. Obviously, there are two types of transistors, as shown
in Fig. 14.27.

he
(i) n-p-n transistor : Here two segments of n-type semiconductor
(emitter and collector) are separated by a segment of p-type
semiconductor (base).
(ii) p-n-p transistor: Here two segments of p-type semiconductor
(termed as emitter and collector) are separated by a segment of

pu T
is
n-type semiconductor (termed as base).
The schematic representations of an n-p-n and a p-n-p
re R
configuration are shown in Fig. 14.27(a). All the three segments of a

bl
transistor have different thickness and their doping levels are also
different. In the schematic symbols used for representing p-n-p and
E
n-p-n transistors [Fig. 14.27(b)] the arrowhead shows the direction of
conventional current in the transistor. A brief description of the three
segments of a transistor is given below:
be C

Emitter: This is the segment on one side of the transistor shown in
Fig. 14.27(a). It is of moderate size and heavily doped. It supplies
a large number of majority carriers for the current flow through
o N

the transistor.
Base: This is the central segment. It is very thin and lightly doped.
Collector: This segment collects a major portion of the majority
carriers supplied by the emitter. The collector side is moderately
doped and larger in size as compared to the emitter.
tt ©

We have seen earlier in the case of a p-n junction, that there is a
formation of depletion region acorss the junction. In case of a transistor
depletion regions are formed at the emitter base-junction and the base-
collector junction. For understanding the action of a transistor, we
have to consider the nature of depletion regions formed at these
junctions. The charge carriers move across different regions of the
transistor when proper voltages are applied across its terminals.
The biasing of the transistor is done differently for different uses.
The transistor can be used in two distinct ways. Basically, it was
invented to function as an amplifier, a device which produces a enlarged
copy of a signal. But later its use as a switch acquired equal
importance. We shall study both these functions and the ways the
no

transistor is biased to achieve these mutually exclusive functions. FIGURE 14.27
First we shall see what gives the transistor its amplifying capabilities. (a) Schematic
The transistor works as an amplifier, with its emitter -base junction representations of a
forward biased and the base-collector junction reverse biased. This n-p-n transistor and
situation is shown in Fig. 14.28, where VCC and VEE are used for creating p-n-p transistor, and
the respective biasing. When the transistor is biased in this way it is (b) Symbols for n-p-n
and p-n-p transistors.
said to be in active state.We represent the voltage between emitter and
base as VEB and that between the collector and the base as VCB. In 491
 Physics
Fig. 14.28, base is a common terminal for the two
power supplies whose other terminals are
connected to emitter and collector, respectively. So
the two power supplies are represented as VEE, and
VCC, respectively. In circuits, where emitter is the
common terminal, the power supply between the

d
base and the emitter is represented as VBB and that
between collector and emitter as VCC.

he
Let us see now the paths of current carriers in
the transistor with emitter-base junction forward
biased and base-collector junction reverse biased.
The heavily doped emitter has a high concentration
of majority carriers, which will be holes in a p-n-p

pu T
is
transistor and electrons in an n-p-n transistor.
These majority carriers enter the base region in
re R large numbers. The base is thin and lightly doped.

bl
So the majority carriers there would be few. In a
p-n-p transistor the majority carriers in the base
E
are electrons since base is of n-type semiconductor.
The large number of holes entering the base from
the emitter swamps the small number of electrons
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there. As the base collector-junction is reverse-
biased, these holes, which appear as minority
carriers at the junction, can easily cross the
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junction and enter the collector. The holes in the
base could move either towards the base terminal
to combine with the electrons entering from outside
or cross the junction to enter into the collector and
reach the collector terminal. The base is made thin
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so that most of the holes find themselves near
the reverse-biased base-collector junction and so
cross the junction instead of moving to the base
FIGURE 14.28 Bias Voltage applied on: (a) terminal.
p-n-p transistor and (b) n-p-n transistor. It is interesting to note that due to forward
bias a large current enters the emitter-base
junction, but most of it is diverted to adjacent reverse-biased base-collector
junction and the current coming out of the base becomes a very small
fraction of the current that entered the junction. If we represent the hole
current and the electron current crossing the forward biased junction by
Ih and Ie respectively then the total current in a forward biased diode is
the sum Ih + I e. We see that the emitter current I E = I h + Ie but the base
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current IB t6; A = 0, B = 1; Hence Y = 1
Therefore the waveform Y will be as shown in the Fig. 14.37.
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EXAMPLE 14.11

FIGURE 14.37

(iii) AND Gate Input Output
An AND gate has two or more inputs and one output. The output Y of
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AND gate is 1 only when input A and input B are both 1. The logic A B Y
symbol and truth table for this gate are given in Fig. 14.38 0 0 0
0 1 0
1 0 0
1 1 1
(b)
FIGURE 14.38 (a) Logic symbol, (b) Truth table of AND gate. 503
 Physics
Example 14.12 Take A and B input waveforms similar to that in
Example 14.11. Sketch the output waveform obtained from AND gate.
Solution
For t ≤ t 1; A = 0, B = 0; Hence Y = 0
For t1 to t2; A = 1, B = 0; Hence Y = 0
For t2 to t3; A = 1, B = 1; Hence Y = 1

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For t3 to t4; A = 0, B = 1; Hence Y = 0
For t4 to t5; A = 0, B = 0; Hence Y = 0

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For t5 to t6; A = 1, B = 0; Hence Y = 0
For t > t 6; A = 0, B = 1; Hence Y = 0
Based on the above, the output waveform for AND gate can be drawn
as given below.

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EXAMPLE 14.12

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FIGURE 14.39
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(iv) NAND Gate
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This is an AND gate followed by a NOT gate. If inputs A and B are both
‘1’, the output Y is not ‘1’. The gate gets its name from this NOT AND
behaviour. Figure 14.40 shows the symbol and truth table of NAND gate.
NAND gates are also called Universal Gates since by using these
gates you can realise other basic gates like OR, AND and NOT (Exercises
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14.16 and 14.17).
Input Output
A B Y
0 0 1
0 1 1
1 0 1
1 1 0
(b)

FIGURE 14.40 (a) Logic symbol, (b) Truth table of NAND gate.
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Example 14.13 Sketch the output Y from a NAND gate having inputs
A and B given below:
EXAMPLE 14.13

Solution
For t < t 1; A = 1, B = 1; Hence Y = 0
For t 1 to t2; A = 0, B = 0; Hence Y = 1
For t 2 to t3; A = 0, B = 1; Hence Y = 1
For t 3 to t4; A = 1, B = 0; Hence Y = 1
504
 Semiconductor Electronics:
Materials, Devices and
Simple Circuits

For t4 to t5; A = 1, B = 1; Hence Y = 0
For t5 to t6; A = 0, B = 0; Hence Y = 1
For t > t 6; A = 0, B = 1; Hence Y = 1

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EXAMPLE 14.13
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FIGURE 14.41
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(v) NOR Gate
It has two or more inputs and one output. A NOT- operation applied
after OR gate gives a NOT-OR gate (or simply NOR gate). Its output Y is
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‘1’ only when both inputs A and B are ‘0’, i.e., neither one input nor the
other is ‘1’. The symbol and truth table for NOR gate is given in
Fig. 14.42.
Input Output
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A B Y
0 0 1
0 1 0
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1 0 0
1 1 0
(b)
FIGURE 14.42 (a) Logic symbol, (b) Truth table of NOR gate.
NOR gates are considered as universal gates because you can obtain
all the gates like AND, OR, NOT by using only NOR gates (Exercises 14.18
and 14.19).

14.11 INTEGRATED CIRCUITS
The conventional method of making circuits is to choose components
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like diodes, transistor, R, L, C etc., and connect them by soldering wires
in the desired manner. Inspite of the miniaturisation introduced by the
discovery of transistors, such circuits were still bulky. Apart from this,
such circuits were less reliable and less shock proof. The concept of
fabricating an entire circuit (consisting of many passive components like
R and C and active devices like diode and transistor) on a small single
block (or chip) of a semiconductor has revolutionised the electronics
technology. Such a circuit is known as Integrated Circuit (IC). The most
widely used technology is the Monolithic Integrated Circuit. The word 505
 Physics
monolithic is a combination of two greek words, monos
means single and lithos means stone. This, in effect,
means that the entire circuit is formed on a single
silicon crystal (or chip). The chip dimensions are as
small as 1mm × 1mm or it could even be smaller. Figure
14.43 shows a chip in its protective plastic case, partly
removed to reveal the connections coming out from the

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‘chip’ to the pins that enable it to make external
connections.
FIGURE 14.43 The casing and

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Depending on nature of input signals, IC’s can be
connection of a ‘chip’.
grouped in two categories: (a) linear or analogue IC’s
and (b) digital IC’s. The linear IC’s process analogue
signals which change smoothly and continuously over a range of values
between a maximum and a minimum. The output is more or less directly

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is
proportional to the input, i.e., it varies linearly with the input. One of the
most useful linear IC’s is the operational amplifier.
re R The digital IC’s process signals that have only two values. They

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contain circuits such as logic gates. Depending upon the level of
integration (i.e., the number of circuit components or logic gates), the ICs
are termed as Small Scale Integration, SSI (logic gates < 10); Medium
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Scale Integration, MSI (logic gates < 100); Large Scale Integration, LSI
(logic gates < 1000); and Very Large Scale Integration, VLSI (logic gates >
1000). The technology of fabrication is very involved but large scale
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industrial production has made them very inexpensive.

FASTER AND SMALLER: THE FUTURE OF COMPUTER TECHNOLOGY
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The Integrated Chip (IC) is at the heart of all computer systems. In fact ICs are found in
almost all electrical devices like cars, televisions, CD players, cell phones etc. The
miniaturisation that made the modern personal computer possible could never have
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happened without the IC. ICs are electronic devices that contain many transistors, resistors,
capacitors, connecting wires – all in one package. You must have heard of the
microprocessor. The microprocessor is an IC that processes all information in a computer,
like keeping track of what keys are pressed, running programmes, games etc. The IC was
first invented by Jack Kilky at Texas Instruments in 1958 and he was awarded Nobel Prize
for this in 2000. ICs are produced on a piece of semiconductor crystal (or chip) by a process
called photolithography. Thus, the entire Information Technology (IT) industry hinges on
semiconductors. Over the years, the complexity of ICs has increased while the size of its
features continued to shrink. In the past five decades, a dramatic miniaturisation in
computer technology has made modern day computers faster and smaller. In the 1970s,
Gordon Moore, co-founder of INTEL, pointed out that the memory capacity of a chip (IC)
approximately doubled every one and a half years. This is popularly known as Moore’s
law. The number of transistors per chip has risen exponentially and each year computers
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are becoming more powerful, yet cheaper than the year before. It is intimated from current
trends that the computers available in 2020 will operate at 40 GHz (40,000 MHz) and
would be much smaller, more efficient and less expensive than present day computers.
The explosive growth in the semiconductor industry and computer technology is best
expressed by a famous quote from Gordon Moore: “If the auto industry advanced as rapidly
as the semiconductor industry, a Rolls Royce would get half a million miles per gallon, and
it would be cheaper to throw it away than to park it”.

506
 Semiconductor Electronics:
Materials, Devices and
Simple Circuits

SUMMARY

1. Semiconductors are the basic materials used in the present solid state
electronic devices like diode, transistor, ICs, etc.
2. Lattice structure and the atomic structure of constituent elements

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decide whether a particular material will be insulator, metal or
semiconductor.
3. Metals have low resistivity (10–2 to 10–8 Ω m), insulators have very high

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resistivity (>108 Ω m–1), while semiconductors have intermediate values
of resistivity.
4. Semiconductors are elemental (Si, Ge) as well as compound (GaAs,
CdS, etc.).

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5. Pure semiconductors are called ‘intrinsic semiconductors’. The presence

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of charge carriers (electrons and holes) is an ‘intrinsic’ property of the
material and these are obtained as a result of thermal excitation. The
number of electrons (ne ) is equal to the number of holes (n h ) in intrinsic
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conductors. Holes are essentially electron vacancies with an effective

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positive charge.
6. The number of charge carriers can be changed by ‘doping’ of a suitable
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impurity in pure semiconductors. Such semiconductors are known as
extrinsic semiconductors. These are of two types (n-type and p-type).
7. In n-type semiconductors, n e >> nh while in p-type semiconductors n h >> ne.
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8. n-type semiconducting Si or Ge is obtained by doping with pentavalent
atoms (donors) like As, Sb, P, etc., while p-type Si or Ge can be obtained
by doping with trivalent atom (acceptors) like B, Al, In etc.
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9. n enh = n i2 in all cases. Further, the material possesses an overall charge
neutrality.
10. There are two distinct band of energies (called valence band an