CBSE Class 12 Physics Notes - Semiconductor Electronics PDF

Summary

These notes provide an overview of semiconductor electronics, covering topics like energy bands, conductors, semiconductors, insulators, and transistors. The information is suitable for secondary school students studying physics.

Full Transcript

Revision Notes Class 12
Physics
Chapter 14 - Semiconductor Electronics

1. ENERGY BANDS IN SOLIDS
In case of solids, there are single energy levels where the atoms are arranged in
a systematic space lattice and therefore the atom is highly influenced by the
neighboring atoms for a single isolated atom. The closeness of atoms will be
resulting in the intermixing of electrons of the neighboring atoms of course, for
the valence electrons, not strongly bounded by the nucleus, in the outermost
shells. Because of the intermixing the number of permissible energy levels will
be increased or there will be significant variations in the energy levels.
Therefore, instead of single energy levels related with the single atom in the
case of a solid, there will be bands of energy levels.

1.1 Conduction Band, Valence Band & Forbidden Energy Gap
The band created by a series of energy levels including the valence electrons
can be defined as valence band. The valence band can be explained as a band
which is inhabited by the valence electrons or a band which is having highest
inhabited band energy.The conduction band can be explained as the least
unfilled energy band. The forbidden energy gap can be defined as the separation
between conduction band and valence band. There will be no permitted energy
state in this gap and therefore electron can’t occupy in the forbidden energy
gap.

1.2 Conductors, Semiconductors and Insulators
Conductors are the materials which can conduct the charge carriers easily.
Insulators are the materials in which the free flow of charge carriers is not
possible. And semiconductors are the materials which is having conductivity in
between insulators and conductors.According to the forbidden band, the
insulators, semiconductors and conductors can be explained as mentioned
below:

1.2.1 Insulators
The forbidden energy band will be very wide in case of insulators. Because of
this information electrons will not be jumped from valence band to conduction

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band. The valence electrons will be bond very tightly to their parent atoms in
insulators. Increase in temperature will be enabling some electrons to move to
the conduction band.

1.2.2 Semiconductors
The forbidden band will be very small in semiconductors. Silicon and
Germanium can be taken as the examples of semiconductors. A semiconductor
material will be the one having electrical characteristics lying between
insulators and good conductors. If a little amount of energy has been supplied,
the electrons can jump from valence band to conduction band easily. As an
example, if the temperature will be enhanced, then the forbidden band will be
reduced such that some electrons are liberated into the conduction band.

1.2.3 Conductors
There will be no forbidden band and the valence band and conduction band
overlap each other, in case of the conductors. Here a lot of free electrons will
be available for the conduction of electricity. A small potential difference
across the conductor will be causing the free electrons for including the electric

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current. The very relevant point in conductors is that because of the absence of
forbidden band, there will be no structure for establishing holes. The
summation of current in conductors will be simply a flow of electrons.

2. SEMICONDUCTORS
Hence, semiconductor can be defined as a substance which is having resistivity
in between conductors and insulators.
Semiconductors will be having the properties mentioned below.
(i) They will be having less resistivity than insulators and more than
conductors.
(ii) The resistance of semiconductor will be reduced with the increase in
temperature and vice versa.
(iii) If suitable metallic impurity such as arsenic, gallium etc. will be added
to a semiconductors, its current conducting characteristics varies
appreciably.

2.1 Impact of temperature of Semiconductors
The semiconductor crystal will be acting like a proper insulator since the
covalent bonds are pretty much strong and no free electrons are available. At
room temperature, some of the covalent bonds will be broken due to the thermal
energy given to the crystal. Due to the breakage of the bonds, some electrons
will be free which were inhabited in the production of these bonds.
The non-appearance of the electron in the covalent bond can be represented by
a small circle. Therefore Hole can be shown as an empty place or vacancy left
behind in the crystal structure. Since an electron is having unit negative charge,
the hole will be similarly having a unit positive charge.

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2.2 Mechanism of conduction of Electrons and Holes
If the electrons are released on the breakage of the covalent bonds, they will be
moving randomly through the lattice of crystal.If an electric field has been
applied, these free electrons will be having a uniform drift which is opposite to
the direction of field applied. This can be referred as the electric current. If a
covalent bond is broken, a hole has been produced. One hole is produced when
one electron set free. This thermal energy will be producing electron-hole pairs-
there will be as many holes as free electrons. These holes can go through the
crystal lattice in a random fashion such as free electrons. The holes drift in the
direction of applied field, if an external electric field is applied. Hence, this can
be referred as electric current.
There will be a strong proneness of semiconductor crystal for producing a
covalent bonds. Hence, a hole will be attracting an electron from the
neighboring atom. Now a valence electron from nearby covalent bond will be
coming for occupying in the hole at A. This will cause in a production of hole
at B. The hole will be therefore successfully shifted from A to B. This hole
will be moving from B to C from C to D and so on.
This movement of the hole in the non-appearance of an applied field will be
random. But the hole gets drifted along the applied field, if an electric field has
been applied.

2.3 Generation and Recombination of Carrier
The electrons and holes will be produced in pairs. The free electrons and holes
will move within the crystal lattice in an irregular manner. There is always a
chance that an electron which is free will be meeting with a hole, in such a
random motion. If a free electron encounter a hole, they will recombine for re-
establishing the covalent bond. Both the free electron and hole will be destroyed
in the process of recombination and cause in the emission of energy as heat.
The energy produced thereby, may in turn will get re-absorbed by another
electron for breaking its covalent bond. In this manner a new electron-hole pair
will be generated.
Hence, the method of splitting of covalent bonds and recombination of
electrons and holes will be taking place simultaneously. If the temperature will
be increased, the rate of generation of electrons and holes will be enhanced.
This is turn increases, the densities of electrons and hole will get increased.
Because of this the conductivity of semiconductor will be increased or

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resistivity decreased. This will be the reason that semiconductors is having
negative temperature coefficient of resistance.

2.4 Pure or Intrinsic Semiconductor and Impure or Extrinsic
Semiconductors
Intrinsic semiconductor can be defined as a semiconductor in which electrons
and holes are solely produced by thermal excitation or a semiconductor in an
extremely pure form is referred as a pure or intrinsic semiconductor. The
number of free electrons will be always equivalent to the number of holes in
intrinsic semiconductor.

2.4.1 Extrinsic Semiconductors
The electrical conductivity of intrinsic semiconductor will be enhanced by the
addition of some impurity in the method of crystallization. The added impurity
will be very small of the order of one atom per million atoms of the pure
semiconductor. This kind of semiconductor can be referred as impurity or
extrinsic semiconductor. The method of infusing impurity to a semiconductor
can be defined as doping.The doping material will be either pentavalent atoms
such as bismuth, antimony, arsenic, phosphorus which are having five valence
electrons or trivalent atoms such as gallium, indium, aluminium, boron which
are having three valence electrons. The pentavalent doping atom can be referred
as donor atom since it is donating one electron to the conduction band of pure
semiconductor. The doping materials can be referred as impurities as they
change the structure of semiconductor crystals which are pure.

2.4.2 N–Type Extrinsic Semiconductor
If a little amount of pentavalent impurity has been added to a pure
semiconductor crystal while the crystal growth, the produced crystal can be
referred as N-type ext1rinsic semiconductor.

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The following points should be remembered in case of N-type semiconductor
(i) The electrons will be the majority carriers while positive holes are
minority carriers, in N-type semiconductor.
(ii) Even though N-type semiconductor is having excess of electrons but it
will be electrically neutral. This will be because of the fact that electrons
are produced by the addition of neutral pentavalent impurity atoms to the
semiconductor. That is, there will be no addition of either positive or
negative charges.

2.4.3 P–Type Extrinsic Semiconductor
If a little amount of trivalent impurity has been added to a pure crystal while
the crystal growth, the produced crystal can be referred as P-type extrinsic
semiconductor.

The following points should be remembered in case of P-type semiconductor:
(i) The majority carriers are positive holes but minority carriers are the
electrons in P-type semiconductor materials.
(ii) The P–type semiconductor will be remaining electrically neutral as the
number of mobile holes under all conditions remains equivalent to the
number of acceptors.

2.5 P–N Junction Diode
If a P-type material has joined to N-type intimately, a P-N junction will be
created. Joining the two pieces a P-N junction will not be formed due to the
surface films and other irregularities create major discontinuity in the crystal
structure. Hence, a P-N junction will be created from a piece of semiconductor
(say, germanium) by diffusing P-type material to one half side and N-type
material to other half side. If P-type crystal has kept in contact with N-type

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crystal so as to produce one piece, the assembly so required will be defined as
P-N junction diode.

2.5.1 Forward Bias
The junction diode can be defined as forward biased, if external d.c. source has
been connected to the diode with p–section connected to positive pole and n–
section connected to negative pole.

2.5.2 Reverse Bias
The junction diode can be defined as reverse biased, if an external d.c. battery
has been connected to junction diode with P–section connected to negative pole
and n–section connected to positive pole.

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NOTE:
P–N JUNCTION can be defined as a device which will be offering low
resistance when forward biased and act as an insulator if reverse biased.
Symbol:

2.6 Junction Diode as Rectifier
An electronic device which will be transforming a.c. power into d.c. power can
be defined as a rectifier.

2.6.1 Principle
If forward biased, Junction diode will be offering a low resistive path and high
resistance if reverse biased.

2.6.2 Arrangement
The a.c. supply will be given across the primary coil ( P ) of step down
transformer. The secondary coil ‘ S ’ of transformer will be in connection to the
junction diode and load resistance R L. The output d.c. voltage will be received
across R L.

2.6.3 Theory
Assume that when first half of a.c. input cycle occurs, the junction diode will
be forward biased. The conventional current will be flowing in the direction of
arrow heats.

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The upper end of R L will be at positive potential with respect to the lower end.
The magnitude of output across R L while first half at any moment will be
proportional to magnitude of current through R L , which in turn will be
proportional to magnitude of the forward bias and which will be dependent
upon the value of a.c. input at that time ultimately.

Hence, output across R L will be changing with respect to a.c. input. While
second half, junction diode will be getting reverse biased and therefore no–
output will be there. Hence, a discontinuous supply will be received.

2.7 Full Wave Rectifier
A rectifier which will be rectifying both halves of a.c. input can be referred as
full wave rectifier.

2.7.1 Principle
Junction Diode will be giving low resistive path if forward biased and high
resistive path if reverse biased.

2.7.2 Arrangement
The a.c. supply has been supplied across the primary coil ( P ) of step down
transformer. The two ends of S–coil (secondary) of transformer will be
connected to P-section of junction diodes D1 and D 2. A load resistance R L
will be connected across the n–sections of two diodes and central tapping of
secondary coil. The d.c. output will be received across secondary.

2.7.3 Theory
Assume that while first half of input cycle upper end of s-coil will be at +ve
potential. The junction diode D1 will be getting forward biased, while D 2 will

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be getting reverse biased. The conventional current because of D1 will flow
along path of full arrows.
If second half of input cycle comes, the conditions will be in opposite manner.
Now the junction diode D 2 will be conducting and the conventional current
will be flowing along path of the dotted arrows. The output during both the half
cycles will be of similar nature as the current during both the half cycles flows
from right to left through load resistance R L.The right end of R L will be at
+ve potential in accordance with left end. Hence, the output will be continuous
in full wave rectifier.

Special usages of P-N junction diode:
a) Zener diode:

The zener diodes can be defined as a heavily doped P-N junction diode where
the operation of the device can occur only in the reverse biased condition. Here
as both p and n sides are heavily dope, the depletion region developed will be
very thin. In this diodes, when the applied reverse bias voltage reaches the
breakdown voltage of the zener diode, we can see a huge variation in the
current. At this time, the reverse voltage will be almost a constant even though
there is significant change in the current occurs. Hence this kind of diodes can

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be used a voltage regulators. The above shown image is showing the Zener
diode as a DC voltage regulator. Here we have to choose the Zener diode in
accordance to the needed output voltage and the series resistance Rs
accordingly.

2.8 Transistor
This will be a three section semiconductor, where three sections are combined
so that the two at extreme ends will be having similar kind of majority carriers.
At the same time, the section that is separating them will be having the majority
carriers in opposite nature. The three sections of transistor can be defined as
emitter ( E ), Base ( B ) and collector (C).

Symbol:

2.8.1 Action of n-p-n Transistor

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Fig. mentions that, the n-type emitter will be forward biased when connected it
to −ve pole of VEB (emitter-base battery) and n-type collector will be reverse
biased when connected it to +ve pole of VCB (collector-base battery).
The majority carriers ( e − ) in emitter will be repelled towards base because of
the forward bias. The base will be having holes as majority carriers but their
number density is small because it is doped very lightly ( 5% ) when we
compare to emitter and collector. Because of the probability of e − and hole
combination in base will be small. Most of e − ( 95% ) cross into collector region
where they will be swept away by +ve terminal of battery VCB.
In corresponds to each electron that is taken by collector, an electron will enter
the emitter from −ve pole of collector – base battery.
When Ie , I b , Ic be emitter, base and collector current respectively then by the
use of Kirchoff’s first law, we can say that,
Ie = I b + Ic

2.8.2 Action of p–n–p Transistor
The p–type emitter will be forward biased when we connect it to +ve pole of
emitter–base battery and p–type collector will be reverse biased when it is
connected to −ve pole of collection - base battery. Here, majority carriers in
emitter, that is holes will be repelled towards base because of forward bias. As
base is lightly doped, it will be having low number density of e −. If hole enters
base region, then only 5% of e − and hole combination will be occurring. Most
of the holes will be reaching the collector and are swept away by −ve pole of
VCB battery.

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2.9 Common base Amplifier
Here, base of the transistor will be common to both emitter and collector.
(a) Amplifier circuit by the use of n-p-n transistor: The emitter will be
forward biased by the use of emitter bias battery (Vcc) and because of this,
resistance of output circuit will be large.

Low input voltage will be applied across emitter – base circuit and amplified
circuit will be received across collector - base circuit. When Ie , I b , Ic be the
emitter, base and collector current then
Ie = I b + Ic … (i)
If current I c is flowing in collector circuit, a potential drop Ic R c will be
happening the resistance connected in collector - base circuit and base
collector voltage will be
Vcb = Vcc − Ic R c...(ii)

(b) Amplifier circuit by the use of p–n–p Transistor

1. If the positive half cycle of input a.c. signal voltage is coming, it supports
the forward biasing of the emitter–base circuit. Due to this, the emitter
current increases and consequently the collector current increases.
2. As I c increases, the collector voltage Vc decreases.

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3. Since the collector is connected to the negative terminal of VCC battery
of voltage VCB , therefore, the reduction in collector voltage shows that
the collector is becoming less negative. This is representing that while
positive half cycle of input a.c. signal voltage occurs, the output signal
voltage at the collector will be also varying through the positive half
cycle.
4. In the same way, when a negative half cycle of input a.c. signal voltage
occurs, the output signal voltage at the collector also varies through the
negative half cycle. Hence, the input signal voltage and the output
collector voltage are in the same phase in common base transistor
amplifier circuit.

2.10 Common Emitter Amplifier
Amplifier circuit by the use of n–p-n transistor
1. The input (emitter base) circuit will be forward biased with battery VBB
of voltage VEB , and the output (collector-emitter) circuit will be reversed
biased with battery VCC of voltage VCE. Because of this, the resistance
of input circuit will be low and that of output circuit will be high. R c will
be a load resistance connected in collector circuit.
2. If a.c. signal voltage has not been applied to the input circuit but emitter
base circuit being closed, assume that Ie , I b and I c be the emitter current,
base current and collector current respectively. Then in accordance to
Kirchhoff’s first law
Ie = I b + Ic

If the positive half cycle of input a.c. signal voltage is considered, it will
be supporting the forward biasing of the emitter-base circuit. Because
of this, the emitter current will be increasing and as a result the collector

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 current will get increased. Because of which, the collector voltage Vc
will be decreased.
3. Since the collector has been connected to the positive terminal of VCE
battery, therefore the reduction in voltage at the collector means the
collector will become less positive, which shows that negative in
accordance to initial value. This shows that while positive half cycle of
input a.c. signal voltage occurs, the output signal voltage at the collector
will be varying through a negative half cycle.
4. If negative half cycle of input a.c. signal voltage is considered, it will be
opposing the forward biasing of emitter-base circuit, because of this the
emitter current will be decreasing and therefore collector current will get
decreased; As a result, the collector voltage Vc gets increased. That is,
the collector will be more positive. This shows that when the negative
half cycle of input a.c. signal voltage occurs, the output signal voltage
will be varying through positive half cycle.

2.11 Common base Amplifier
A.c. current gain: This can be explained as the ratio of variation in collector
current as fixed collector voltage. It is represented by  ac.
 I 
 ac =  c 
 Ie 
 VCB = const.

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Voltage gain: This can be referred as the ratio of variation in output voltage to
the variation in input voltage. It can be represented as A.

Av =
( ΔIc ) R out = ΔIc × R out
( ΔIe ) R in ΔIe R in
Or A v =α AC × resistance gain,
R
Where out can be referred as resistance gain.
R in

Power gain: This can be explained as the ratio of variation in output power
to the variation in input power. Hence,
change in output power ( Ic ) R out
a.c. power gain= =
change in input power ( Ie ) R in
I 2 c R out
= 2 
I e R in
Or a.c. power gain= 2 ac  resistance gain

2.12 Common Emitter Amplifier
A.c. current gain: The ratio of the variation in collector to the variation in base
current can be defined as a.c current gain. It is represented as ac.
Hence,
 I 
ac =  c  [Vce = const.]
 Ib 
The value of this quantity is quite large as compared to 1 and it lies between
15 to 50.

Voltage gain: The ratio of the variation in output voltage to the
variation in input voltage can be referred as voltage gain. It is represented as A

Av =
( ΔIc )×R out = ΔIc × R out
( ΔIb )×R in ΔIb R in
Or A v =β ac × resistance gain.

A.c. power gain: The ratio of the variation in output power to the variation in
input power can be defined as A.c power gain.

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 change in output power ( Ic ) R out
a.c. power gain= =
change in input power ( Ib ) R in
Or a.c. power gain=2 ac  resistance gain.

2.13 Relation between  and 
In the case of both the types of amplifier, we will be having
ie = ib + ic
Divide both sides of the equation given above by I c , we will obtain,
ie ib
= +1
ic ic
1 1 1 1 (1-α)
 =( )+1 or =( )-1=
α β β α α
α
Or β=
(1-α)
Similarly, The relation of  in terms of  ,

=
1+ 

3. ANALOG SIGNALS
Analog signal can be defined as the signals which is varying continuously with
respect to time. A typical analog signal has been represented in the diagram
below. Circuit which has been used for the generation of analog signal can be
defined as the analog electronic circuit.

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4. DIGITAL SIGNALS
Signals which are having either of the two levels, 0 or 1 , can be defined as
digital signals.

5. LOGIC GATES
A gate can be explained such that a digital circuit which is either stopping a
signal or permitting it to pass through it. A logic gate will be an electronic
circuit which will be creating logical decisions. Logic gate will be having one
or more inputs but only one output. Logic gates are considered as the basic
building blocks for every digital systems. Variables used at the input and output
will be 1's and 0's. The three basic logic gates are mentioned below:
(i) OR gate
(ii) AND gate
(iii) NOT gate

5.1 OR Gate
OR gate can be considered as an electronic equipment that is combining A and
B for ptoviding Y as output. Two inputs are A and B and output is Y in this
figure. In Boolean algebra OR is shown as +.

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Truth Table: This can be defined as a table which is providing an output state
for all possible input combinations.
Logic operations of OR gate has been provided in its truth table for all possible
input combinations.
Input Output
A B Y
0 0 0
0 1 1
1 0 1
1 1 1

5.2 AND Gate
There are two or more inputs and one output in an AND gate. In Boolean
algebra AND has been denoted as a dot (.).

Truth Table
Input Output
A B Y
0 0 0
0 1 0
1 0 0
1 1 1

5.3 NOT Gate
NOT gate can be considered as an electronic device which is having one input
and one output. This circuit will be known as the same as the output is NOT
the similar one as input.

Boolean expression for NOT gate is Y = A.

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Truth Table:
Input Out
put
A Y
0 1
1 0

5.4 NOR Gate
A NOR gate will be having two or more inputs and only one output. Here, NOR
gate is a NOT-OR gate actually. When a NOT gate has been connected at the
output of an OR gate, we will be getting NOR gate as represented in the diagram
below and its truth table in table.

Truth Table:
A B Y Y
0 0 0 1
0 1 1 0
1 0 1 0
1 1 1 0

Boolean expression for NOT gate will be Y = A + B and this can be read as Y
equals A OR B negated. A NOR function will be the reverse of OR function.

Truth Table:
Input Output
A B Y
0 0 1
0 1 0

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 1 0 0
1 1 0

5.5 NAND Gate
A NAND gate will be having two or more inputs and only one output. A NAND
gate is actually a NOT–AND gate. When a NOT gate has been connected at the
output of a AND gate, we will be getting NAND gate as represented in the
diagram and its truth table has been shown in table.

A B Y Y
0 0 0 1
0 1 0 1
1 0 0 1
1 1 1 0
Boolean expression for NAND gate, will be Y = A  B and is read as Y equals
A and B negated. Logical symbol of NAND gate has been represented in the
diagram and its truth table in table.

Truth Table:
Input Output
A B Y
0 0 1
0 1 1
1 0 1
1 1 0
Similar to NOR gate, NAND gate will also be useful to realize all basic gates:
OR, AND and NOT. Therefore it is also called as Universal Gate.

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Universal Gate:
A universal gate can be defined as a logic gate which can be used to perform
any Boolean function with no utilization of any other type of logic gate.
Examples of universal gates are NOR gate and NAND gate.

Integrated circuits:
The conventional process of creating circuits will be to choose components
such as transistor, diodes, R, L, C etc., and connect them using soldering wires
in the required manner. The commonly used technology will be the Monolithic
Integrated Circuit. These kind of circuits is contained of logic gates. When we
depend upon the level of integration (that is, the number of circuit components
or logic gates), the ICs can be defined as Small Scale Integration, SSI (logic
gates < 10), Medium Scale Integration, MSI (logic gates < 100), Large Scale
Integration, LSI (logic gates < 1000) and Very Large Scale Integration, VLSI
(logic gates > 1000).

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