Diode Topics Complete Notes PDF

Summary

Lecture notes on diode topics, covering various aspects of diodes and semiconductor devices. Includes information on practical work, calculation procedures, and characteristics analysis.

Full Transcript

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 HANDOVER THE TITLE OF PROJECT(CA3)
CONDITIONS-
- ARDUINO BASED PROJECT only
- SAME TITLE NOT ALLOWED FOR OTHER GROUP
- MAXIMUM 4 STUDENT IN GROUP, handover Group
project title, first come on first basis
- Project Report Common for Group(single common
copy)
- On Saturday, you may discus any issue/points regrading
Project

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IN CASE, ANY STUDENT, WHO IS NOT ABLE TO
DOWNLOAD AND INSTALL PROTEUS ON YOUR
LAPTOP, YOU COME WITH PENDERIVE, collect
softcopy AND RUN & INSTALL ON YOUR OPERATING
SYSTEM OR LAPTOP

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BASIC ABOUT CONDUCTOR , SEMICONDUCTOR and INSULATOR

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n-Type Semiconductors

N-type semiconductors are extrinsic semiconductors in
which dopant atoms can provide additional conduction
electrons to the host material (e.g. phosphorus in silicon).

p-Type Semiconductors

To enhance the number of free charge carriers, a p-type (p
for “positive”) semiconductor is formed by adding a certain
type of atom to the semiconductor.
The goal of p-type doping is to produce a large number of
holes.
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 MAIN USE OF PN JUNCTION DIODE

A p-n junction diode is used for passing the
current in one direction. It is a two-terminal
or two electrode semiconductor device.

This diode helps in stopping the current in
the reverse or opposite direction.

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 Characteristics- PN Junction Diode

A PN Junction Diode is one of the simplest
semiconductor devices around, and which has
the electrical characteristic of passing current
through itself in one direction only.

Unlike a resistor, a diode does not behave
linearly with respect to the applied voltage.

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 Principle of PN junction diode

A p–n junction diode allows charge carriers to
flow in one direction, but not in the opposite
direction

Negative charge carriers (electrons) can easily
flow through the junction from n to p but not
from p to n, and the reverse is true for positive
charge carriers (holes).

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Applications of P-N Junction Diode

It can be used as a solar cell. When the diode
is forward-biased, it can be used in LED
lighting applications.

It is used as rectifier in many electric circuits
and as a voltage-controlled oscillator in
varactors.

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 -in electrical switches and are used in surge
protectors because they can prevent a spike in the
voltage.

Diodes are used in circuit protection due to their
ability to restrict electrical current to flow in
only one direction.
This trait is useful because some electrical
components and devices will be damaged or
malfunction if current flows in the wrong
direction.
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 LEDs are used in sensors and laser devices.

Zener diodes are used as voltage regulators.

Diodes help in performing digital logic.

Diodes are useful in the construction of
logic gates, which are the building blocks
of digital electronics. one can create gates
that perform basic logical functions like
AND, OR, and NOT.

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Advantages of P-N Junction Diode

To convert alternating current (AC) to direct
current (DC), a p-n junction diode can be used
(DC).

These diodes are found in power supplies. If the
diode is forward biased, current can flow.
However, if it is reverse biased, it prevents
current flow.

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 Disadvantages of pn junction diode

-PN junction diode don't work in reverse biased
mode.

-It can be overstressed during breakdown in voltage
referencing.

-May cause delay in high-scale operations.

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 The PN Junction
Metallurgical
Steady State
Na Junction Nd

- - - - - + + + + +
When no external source
P - - - - - + + + + + is connected to the pn
n
- - - - - + + + + + junction, diffusion and
- - - - - + + + + +
Space Charge
drift balance each other
ionized
acceptors
Region ionized out for both the holes
donors
E-Field and electrons
_ _
+ +
h+ drift = h+ diffusion e- diffusion = e- drift

Space Charge Region: Also called the depletion region. This region includes
the net positively and negatively charged regions. The space charge region
does not have any free carriers. The width of the space charge region is
denoted by W in pn junction formula’s.

Metallurgical Junction: The interface where the p- and n-type materials meet.

Na & Nd: Represent the amount of negative and positive doping in number of
carriers per centimeter cubed. Usually in the range of 1015 to 1020.
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 The Biased PN Junction
Metal
Contact
“Ohmic
Contact”
_
+
(Rs~0)
Applied
P Electric Field n

I

_
+
Vapplied
The pn junction is considered biased when an external voltage is applied.
There are two types of biasing: Forward bias and Reverse bias.
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 Forward Biased PN Junction Diode
When a diode is connected in a Forward Bias condition, a negative voltage is applied to the N-type material and a
positive voltage is applied to the P-type material. If this external voltage becomes greater than the value of the
potential barrier, approx. 0.7 volts for silicon and0.3voltsfor germanium, the potential barriers opposition will be
overcome and current will start to flow. This is because the negative voltage pushes or repels electrons towards
the junction giving them the energy to cross over and combine with the holes being pushed in the opposite
direction towards the junction by the positive voltage. This results in a characteristics curve of zero current
flowing up to this voltage point, called the knee on the static curves and then a high current flowthrough the
diode with little increase in the external voltage as shown below.

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 When a diode is connected in a Forward Bias condition, a
negative voltage is applied to the N-type material and a positive
voltage is applied to the P-type material.

If this external voltage becomes greater than the value of the
potential barrier, approx. 0.7 volts for silicon and0.3voltsfor
germanium, the potential barriers opposition will be overcome
and current will start to flow.

This is because the negative voltage pushes or repels electrons
towards the junction giving them the energy to cross over and
combine with the holes being pushed in the opposite direction
towards the junction by the positive voltage.

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 Reverse Biased PN Junction Diode
When a diode is connected in a Reverse Bias condition, a positive
voltage is applied to the N-type material and a negative voltage is applied
to the P-type material. The positive voltage applied to the N-type material
attracts electrons towards the positive electrode and away from the
junction, while the holes in the P-type end are also attracted away from
the junction towards the negative electrode. The net result is that the
depletion layer grows wider due to a lack of electrons and forms a
potential barrier which prevent the current from flowing through the
semiconductor material.

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 PN Junction Breakdown
An electrical breakdown of any material such as the
conductor, semiconductor, and insulator can occur
due to two different phenomena known as a) Zener
Breakdown b) Avalanche Breakdown.

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 Zener Breakdown
When the reverse bias voltage is applied across the pn
terminals, the depletion region begins to increase. As a
result, more electrons and holes are generated.
These electrons and holes produce a very powerful electric
field across the junction of the diode. The magnitude of the
electric field will depend on the magnitude of the applied
reverse voltage.
The electric field exerts an electron force which is present in
the valence band. This will enter the conduction band, and
the conduction process begins.
This phenomenon is called Zener breakdown.
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 Avalanche breakdown
The free electrons move across the depletion region of the
diode. They possess velocity, and the electrons acquire kinetic
energy. Due to the presence of velocity, the minority carriers
randomly move inside the diode. It collides with stationary
electrons held to the atom by covalent bonding.
The covalent bonding gets broken by bound electrons, and
the conduction process begins. The electrons transfer the
kinetic energy to stationary electrons which makes them
move. As the magnitude of the reverse bias voltage increases,
the energy rises. The resulting collision produces a current,
which causes the breakdown of the diode.
This breakdown is called an avalanche breakdown.
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DIFFERENCE BETWEEN ZENER AND AVALANCHE BREAKDOWN

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 Properties of Diodes
The Shockley Equation
The transconductance curve on the previous slide is characterized by
the following equation:

ID = IS(eVD/VT – 1)
As described in the last slide, ID is the current through the diode, IS is
the saturation current and VD is the applied biasing voltage.
VT is the thermal equivalent voltage and is approximately 26 mV at room
temperature. The equation to find VT at various temperatures is:
VT = kT
q
k = 1.38 x 10-23 J/K T = temperature in Kelvin q = 1.6 x 10-19 C
 is the emission coefficient for the diode. It is determined by the way
the diode is constructed. It somewhat varies with diode current. For a
silicon diode  is around 2 for low currents and goes down to about 1 at
higher currents
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 Types of Diodes and Their Uses

PN Junction Are used to allow current to flow in one direction
Diodes: while blocking current flow in the opposite
direction. The pn junction diode is the typical diode
that has been used in the previous circuits.

A K P n
Schematic Symbol for a PN Representative Structure for
Junction Diode a PN Junction Diode

Zener Diodes: Are specifically designed to operate under reverse
breakdown conditions. These diodes have a very
accurate and specific reverse breakdown voltage.

A K

Schematic Symbol for a
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 Types of Diodes and Their Uses

Light-Emitting Light-emitting diodes are designed with a very large
Diodes: band gap so movement of carriers across their
depletion region emits photons of light energy.
Lower band gap LEDs (Light-Emitting Diodes) emit
infrared radiation, while LEDs with higher band gap
energy emit visible light. Many stop lights are now
starting to use LEDs because they are extremely
bright and last longer than regular bulbs for a
relatively low cost.

The arrows in the LED
A K representation indicate
emitted light.
Schematic Symbol for a
Light-Emitting Diode

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 Types of Diodes and Their Uses

Photodiodes: While LEDs emit light, Photodiodes are sensitive to
received light. They are constructed so their pn
junction can be exposed to the outside through a
clear window or lens.
A K In Photoconductive mode the saturation current
increases in proportion to the intensity of the
received light. This type of diode is used in CD
 players.
A K
In Photovoltaic mode, when the pn junction is
exposed to a certain wavelength of light, the diode
Schematic Symbols for generates voltage and can be used as an energy
Photodiodes source. This type of diode is used in the
production of solar power.

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PIECEWISE LINEAR EQUIVALENT MODEL

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A piecewise linear model of a diode is an approximate
representation of the diode's current-voltage (I-V)
characteristic using a series of linear segments. This model
simplifies the complex non-linear behavior of a diode and
allows for easier analysis and modeling in circuit design.

The piecewise linear model typically consists of three main regions:
Forward-bias region: In this region, the diode exhibits a relatively low
voltage drop (typically around 0.7V for silicon diodes) as the current
increases. This region can be modeled as a constant voltage source in
series with a small resistance.
Reverse-bias region: In this region, the diode behaves like an open
circuit, allowing negligible current to flow until the reverse breakdown
voltage is reached. The reverse-bias region is often modeled as an
infinite resistance.

Breakdown region: Beyond the reverse breakdown voltage, the diode
enters the breakdown region, where a rapid increase in current occurs.
This region is typically modeled as a constant voltage source in series
with a small resistance.
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WHAT YOU LEARNED FROM VI
CHACTERSTICS OF PN JUNCTION DIODE ?

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WHAT YOU LEARN FROM VI CHACTERSTICS OF
PN JUNCTION DIODE

PN junction diode conducts current only in one
direction – i.e. during forward bias.
During forward bias, the diode conducts current
with an increase in voltage.
During reverse bias, the diode does not conduct
with an increase in voltage.

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 MCQ Question-2
During reverse bias, a small current
develops known as
a) Forward current
b) Reverse current
c) Reverse saturation current
d) Active current

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 Answer:C
When the diode is reverse biased, a small current
flows between the p-n junction which is of the order
of the Pico ampere. This current is known as reverse
saturation current.

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MCQ Question -3

When the diode is reverse biased with a
voltage of 6V and Vbi=0.63V. Calculate
the total potential.
a) 6V
b) 6.63V
c) 5.27V
d) 0.63V

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Answer: b
Explanation: Vt=Vbi+VR
=0.63+6
=6.63V.

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What will be the output of the following circuit?
(Assume 0.7V drop across the diode)
The output of the following circuit is 11.3V

a) 12V
b) 12.7V
c) 11.3V
d) 0V

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Answer: c
V=12-0.7
=11.3V.

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MCQ, Question-5
How many junction/s do a diode
consist?
a) 0
b) 1
c) 2
d) 3

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 Answer:B
Explanation: Diode is a one junction
semiconductor device which has one cathode
and anode. The junction is of p-n type.

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 Practical work

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The 1N4001 diode belongs to the family of the 1N400x diode series,
which are most commonly used in household electronic appliances.
It allows the flow of current only in one direction, that is from anode
terminal to cathode terminal just like a normal diode.
It is referred to as a general-purpose rectifier diode used for rectification
purposes. The 1N4001 diode is shown in the figure below.

The current carrying capacity is of maximum 1 Ampere and can tolerate
up to a peak value of 30 Amps.
This type of silicon diode is mainly used in designing circuits with less
than 1 Ampere.
The negligible reverse current is 5 microAmps. The reverse peak
voltage, where the diode can withstand is up to a maximum of 50 Volts.

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 Features & Specifications
The average forward current of 1N4001 diode is 1 Ampere
The RMS reverse voltage is 35 Volts
The reverse current is 5 microAmps
The peak repetitive reverse DC voltage is 50 Volts
The maximum forward voltage is 1.1 Volts.
The maximum reverse current is 10 microAmps
It operates at -55 to +175°C maximum temperature ranges
The maximum output current will be 1 Amp.
The maximum reverse voltage and DC voltage rating is 50
Volts
The maximum power dissipation is 3 Watts.

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 VIRTUAL LAB LINK FOR PN JUNCTION DIODE PRACTICAL

http://vlabs.iitkgp.ernet.in/be/exp5/forwardbiaseddiode_si.html

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Numerical PROBLEM on DIODE

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 Numerical PROBLEM-1
Calculate the forward bias current of a Si diode
when forward bias voltage of 0.4V is applied, the
reverse saturation current is 1.17×10-9A and the
thermal voltage is 25.2mV.

a) 9.156mA
b) 8.23mA
c) 1.256mA
d) 5.689mA

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 NUMERICAL PROBLEM 2
Calculate the reverse saturation current of a
diode if the current at 0.2V forward bias is
0.1mA at a temperature of 25°C and the
ideality factor is 1.5.
a) 5.5x 10-9 A
b) 5.5x 10-8 A
c) 5.5x 10-7 A
d) 5.6x 10-10 A

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 NUMERICAL PROBLEM 3

Find the applied voltage on a forward biased
diode if the current is 1mA and reverse
saturation current is 10-10. Temperature is
25°C and takes ideality factor as 1.5.

a) 0.658V
b) 0.726V
c) 0.526V
d) 0.618V
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 NUMERICAL PROBLEM 4
What will be the current I in the circuit diagram below. Take terminal
voltage of diode as 0.7V and I0as 10-12A.

a) 2.4mA
b) 0.9mA
c) 1mA
d) 4mA

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