Semiconductor Devices-Intro PDF

Summary

This document provides an introduction to semiconductor devices. It covers energy band diagrams, classification of semiconductors, intrinsic and extrinsic semiconductors, and p-n junction theory. The document also briefly touches on solid materials and related concepts.

Full Transcript

SEMICONDUCTOR DEVICES

DR. U.P.SINGH
Senior Professor
School of Electronics Engineering
E-mail : [email protected]

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Introduction to Semiconductor and P-N Junction
theory
Energy band diagram and classification, Semiconductor under
equilibrium Condition (n0, p0 and intrinsic carrier concentration),
Intrinsic and extrinsic semiconductor, Density states and Fermi
level, Drift and diffusion current, Carrier generation and
recombination, Excess carrier concentration, Continuity
equation, Carrier lifetime,
Qualitative description of charge flow in a p-n Junction, Junction
Theory (concept of potential barrier, built in electric field,
depletion layer width, and junction capacitance qualitative
only), PN Junction operation under bias, and I~V relationship.

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SOLID : A solid consists of atoms, ions or molecules packed closely
together, and the forces that hold them together in place
give rise to the distinctive properties of the various kinds of
solids.

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 Crystalline

Amorphous

Polycrystalline
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 What is Semiconductor ?
The conductivity of semiconductors occupies the area
between conductors and insulators.
The conductivity can range over many orders of magnitude.
The conductivity of semiconductors can be adjusted through
a number of means, each related to the physical properties
of semiconductors.
Typical methods for adjusting the conductivity of a
semiconductor are:
a. Temperature
b. Purity (Doping)
c. Optical excitation
d. Electrical excitation.

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 What is a Semiconductor?– contd.
Low resistivity => “conductor”
High resistivity => “insulator”
Intermediate resistivity => “semiconductor”
– conductivity lies between that of conductors
and insulators

Large variation in conductivity ??
Concentration of Electrons

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 conductivity σ (S/cm)=1/(resistivity ρ (Ω -cm))
The conductivity of a semiconductor is generally sensitive to temperature,
illumination, magnetic field and minute amounts of impurity atoms.

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Element semiconductors

Germanium
– In the early 1950s, was the major semiconductor material
Silicon
– Better device properties
– High quality silicon dioxide
– Cheaper
– Abundant

9
 The other important criteria for semiconductors are :

– Energy Band Gap (eV)
– Carrier concentration or density (cm-3)

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 Energy Band Theory in Solids
The physical basis of energy bands is quantum
mechanics
Atoms have …
oquantized electron states
odiscrete energies
oa specific spatial distribution of electrons
that is, electron orbitals have a certain shape
s-type orbitals have spherical symmetry
p-type orbitals have a lobe-shaped symmetry

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 Energy Band Formation in Solids
Energies of the electrons in an atom can’t
have arbitrary value, but only some definite
values given by quantum mechanical laws.
The electrons have a well defined energy
levels for a free atom.
If the atom belongs to a crystal where it is
surrounded by neighboring atoms, then the
energy levels are modified.
Pauli exclusion principle, which states that no two electrons or other
fermions can have the same quantum numbers.

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 Band formation
Si: 1s2,2s2,2p6,3s2,3p2

d c b a

Interatomic spacing r
Conductor: Valence band partially filled (half full) Cu.
or Conduction band overlaps the valence band

Na: 1s2,2s2,2p6 3s1
Mg: 1s2,2s2,2p6 3s2

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 Band Overlap
Example: Magnesium (Mg; Z =12): 1s22s22p63s2
– Might expect to be insulator; however, it is a metal
– 3s-band overlaps the 3p-band, so now the
conduction band contains 8N energy levels, while
only have 2N electrons
– Other examples: Zn, Be, Ca, Bi
 Energy Band Diagram

Conduction band Ec

Band gap
Eg

Ev
Valence band

Energy band diagram shows the bottom edge of conduction
band, Ec , and top edge of valence band, Ev.
 Ec and Ev are separated by the band gap energy, Eg.
 Semiconductor
 Elemental : Si and Ge
 Compound : GaAs, CdTe, InP etc.
 Direct band gap and indirect band gap

One distinguished feature of
semiconductor is the location of
the conduction band energy
minimum w.r.t. the valence band
maximum on the E-k diagram

Slide 1-20
 Measuring the Band Gap Energy by Light Absorption
electron
Ec
photons
Eg
photon energy: hv > Eg
Ev

hole

Eg can be determined from the minimum energy (hn) of
photons that are absorbed by the semiconductor.
Bandgap energies of selected semiconductors
Semi-
conductor InSb Ge Si GaAs GaP ZnSe Diamond

Eg (eV) 0.18 0.67 1.12 1.42 2.25 2.7 6
 The main characteristic of
a semiconductor element
is that it has four
electrons in its outer or
valence orbit.

The unique capability of semiconductor
atoms is their ability to link together to form
a physical structure called a crystal lattice.

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 The longest wavelength thatcan be absorbed by Silicon, which has the
bandgap of 1.12 eV, is 1 mm. If the longest wavelength that can be
absorbed by another material is 0.87 mm, then the bandgap of the
material is ??

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Direct Band gap Materials

Actual Band structure are more
complex.
Plot between energy(E) and
momentum(k=ħk) called E-K diagram.
For Direct band materials, minimum of
CB and Max of VB are same for
k=0,so min energy transition without
change in ‘k’.
When electron fall from CB to VB give
off energy difference Eg as photon of
light.
In direct semiconductor such as
GaAs,GaP, an electron in the
conduction band can fall to an empty
state in the valence band, giving off
the energy difference Eg as a photon
of light.
Example:GaAs,GaP
 Indirect Band gap Materials
In an indirect semiconductor such as Si,
the electron in the conduction band
cannot fall directly to the valence band
but must undergo a momentum change
as well as changing its energy.When the
electron falls it must go some changes in
energy as well as momentum.
The electron may go to defect state (Ef)
with in the band gap and involves a
change in ‘k’.
The energy given as heat to the lattice
rather than photon.
It is important for deciding which
semiconductors can be used in devices
requiring light output.
Example: Silicon, Germanium
 Intrinsic and Extrinsic Semiconductor
 The semiconductor has a filled V.B. and empty C.B. at 0 oK
 As the temperature is raised – increase in C.B. electrons –
thermal excitation across the band gap
 After the electrons are excited to the C.B., the empty states
left in the V.B. can contribute to the conduction process.
 The introduction of impurities has an important effect on
the energy band structure and on the availability of charge
carriers.
 The concentration( cm-3) of conduction electrons and holes
in a semiconductor can be modulated in several ways
 By adding special impurity atoms
 By applying an electric field
 By changing the temperature (thermal excitation)
 By irradiation (optical excitation)
Bond Model

Band Model

Intrinsic carrier conc. (@RT)
GaAs 2x106 cm-3
Si 1x1010 cm-3
Ge 2x1013 cm-3

Why the carrier conc. Is
different for different semi-
conductor?

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The extra electron on the phosphorous atom is easily removed and becomes a
free electron without generating a hole.
The phosphorous atom becomes positively charged (ionized).

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 The boron atom ‘steals’ an electron from a neighboring Si atom to complete
the four bonds with the surrounding Si atoms, generating a hole at the
neighboring Si atom.
The boron atom becomes negatively charged (ionized).

All the dopants are
ionized at room
temperature!!

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 P-type Semiconductor

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 The situation for the group III-V semiconductor is different
Group VI impurities (S, Se,Te) acts as donors in GaAs,
these impurities substitute the Gr V atoms (As)
Group II impurities (Be,Zn,Cd) substitute for Gr III (Ga) in
GaAs
An interesting case arises when III-V compound is doped
with Gr IV (e.g. Si)
If the impurity resides on Gr III  Donors (more common)
If the impurity resides on Gr V  Acceptors
Such impurities are called Amphoteric Impurities.
Semiconductor that can be made both n or p type are said
to be Ambipolar

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 FERMI ENERGY OR FERMI LEVEL

In dealing with large number of particles, we are interested
only in statistical behaviour of the group as a whole rather
than the behaviour of each individual particle

Likewise in crystal, the electrical characteristics will be
determined by the statistical behaviour of a large number of
electrons.
Statistical Laws
 Maxwell Boltzmann Probability Function
- particles are considered to be distinguishable
- with no limit to the numbers of particles allowed in each energy state
( behaviour of gas molecules in a container at very low pressure)
 Bose Einstein Function
- Particles are indistinguishable
- no limit to the number of particles permitted in each quantum states
( e.g. behaviour of photons, black body radiation )
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 Fermi Dirac Distribution Function
- particles are indistinguishable, identical
- one particle is permitted in each quantum states
- These particles must obey Pauli’s exclusion principle
(e.g. electrons in a crystal, such particles are called
FERMIONS
Pauli’s Exclusion Principle: No two electron in an atom can be in the same
quantum state

The function f(E) specifies, under equilibrium
conditions, the probability that an available 1
state at an energy E will be occupied by an f (E) 
electron. 1  e ( E  EF ) / kT
EF is called the Fermi energy or the Fermi
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DR.UDAI P. SINGH 41
 To understand the meaning of the distribution function and the Fermi
Energy we can plot the distribution function vs Energy
Consider T  0K
For E < Ef 1

For E > Ef 0

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T>0K
If E = Ef ,
then f(E) = 1/2

 At 0K, the distribution function f(E) takes a simple rectangular shape.
It implies that all states upto Ef are filled with electrons and states above Ef are
empty
 At temperature greater then 0K, some probability exists for states above Fermi
Level to get filled with electrons
 At any temperature (T1) , there is a probability f(E) that states above Ef are
filled. A corresponding probability 1-f(E) exists that states below Ef are empty
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 Fermi energy defines as that energy for which
the probability of occupancy f(E) equals ½
OR
An energy state at the Fermi Level has a
probability of ½ being occupied.

1-f(E) is the probability that a state at energy E
is unoccupied/empty.
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 Intrinsic
Semiconductor
An insulator/intinsic semiconductor at T = 0 K has a filled valence band and an
empty conduction band. The Fermi level lies midway between these bands. The
Fermi–Dirac probability that an energy state E is occupied at T > 0 K is shown to
the left.
 Charge carriers in Semiconductor
The distribution(w.r.t. energy) of the electrons in the CB is
given by density of allowed quantum states times the
probability that a state is occupied by an electron.

n(E) = N(E) F(E)

Density of quantum states in CB Fermi Dirac probability function

The total electron concentration per unit volume in the CB is found by
integrating the above equation over the entire CB energy
n(E) =∫ N(E) F(E) dE

The lower limit of the integration is Ec and the upper limit is taken as infinity

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The integral is complicated. For ease of calculation, one assume (E-Ef) > 3kT,
with this limitation the F.D. distribution function can be approx. by Boltzman
distribution

1
f (E) 
1  e ( E  EF ) / kT
For E > Ef

The reason for restricting the energy levels to values greater than Ef is that
an energy level E < Ef in above equation make the probability greater than
1, which is meaningless.

N(E) is given as For E > Ec

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 n or no= Nc exp (Ef-Ec/kT)

Nc is effective density of states in the CB

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Similarly, the distribution (w.r.t. energy) of holes in the VB is
the density of allowed quantum states in the VB multiplied
by the probability that a state is not occupied by an electron

The total hole conc. per unit volume is found by integrating this function
over the entire VB energy

Where,

Commonly p(E), is written as po
(equilibrium hole conc.)

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 The Intrinsic carrier conc.

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  The distance between the bottom of the CB and the
Fermi energy is a logarithmic function of donor
concentration
 As the donor concentration increases, the F.L. moves
closer to the CB.
 Conversely, if the F.L. moves closer to the CB then the
electron concentration in the CB is increasing

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It is useful to express electron and hole densities in terms
of the intrinsic carrier concentration ni and the intrinsic
Fermi level Ei

Also,

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 From (1)

Substituting in (3)

Similarly,

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 PROBLEMS

Si at RT (300 K) contains an acceptor impurity concentration of NA
=1016 cm-3. Determine the concentration of donor impurity atoms
that must be added so that the Si is n-type and the Fermi energy is
0.2 eV below the CB edge. Given NC==2.8x1019 cm-3

= 2.8x1019 exp (-7.7221)

= 2.8x1019 x 0.000443 = 1.24x1016 cm-3

ND= 1.24X1016 +NA
=1.24X1016 + 1016
=2.24X1016 cm-3
Solve Prob. 15,
Chap 1
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The intrinsic carrier concentration of Si sample at 300 K is 1.5x1016 m-3.
If after doping, the number of majority carriers is 5x1020m-3, the minority
carrier density is

4.50 x1011 m-3

Silicon bar is doped with donor impurities ND = 2.25x1015 atoms/cm3.
Given the intrinsic carrier conc. of Si at RT is 5x1010 cm-3. Assuming the
complete ionization, the equilibrium electron and hole concentrations
are

no= 2.25x1015 cm-3 po= 1x105 cm-3

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Electron density as a function of temperature for a Si sample with a donor
concentration of 1015 cm-3.

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 Figure (previous slide) shows electron density in Si as a function of
temperature for a donor concentration of ND=1015cm-3.
 At low temperatures, the thermal energy in the crystal is not
sufficient to ionize all the donor impurities present. Some electrons
are “frozen” at the donor level and the electron density is less than
the donor concentration.
 As the temperature is increased, the condition of complete
ionization is reached,  nn=ND
 As the temperature is further increased, the electron concentration
remains essentially the same over a wide temperature range. This
is the extrinsic region.
 However, as the temperature is increased even further, one reach a
point where the intrinsic carrier concentration becomes comparable
to the donor concentration.
 Beyond this point, the semiconductor becomes intrinsic.
 The temperature at which the semiconductor becomes intrinsic
depends on the impurity concentrations and the bandgap value
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 A Semiconductor device requires n-type material, it is to be operated at 400 K.
Would Si doped with 1015 atoms/cm3 of As be useful in this application?
Could Ge doped with 1015 cm-3 Sb be used?

At 400K
Si  1013 cm-3
Ge  5x1015 cm-3

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 Drift and Diffusion Current
Carrier motion is caused by two conditions :

 The application of an electric field whose force accelerates the
carriers and, second a difference of carrier concentration between two
points causes carriers to move by diffusion from region of high conc.
to regions of low conc.
 Electrons and holes in semiconductors are in constant motion
because of the thermal energy they receive. Since they are in motion,
they are not associated with any particular lattice position.
 At any one time, the electrons and holes move in random directions
with a mean random velocity. Because of the motion in random
directions, the current resulting from the motion of all the carriers in
any one direction is zero.
 The average distance between each collision is called the mean free
path.

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 Diffusion Current
It is possible to have a non-uniform concentration of particles in a
semiconductor.

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 Similarly for electrons

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Assume that, in an n-type semiconductor at T = 300K, the
electron concentration varies linearly from 1 × 1018 to
7 × 1017 cm-3 over a distance of 0.1 cm. Calculate the
diffusion current density if the electron diffusion coefficient
is Dn = 22.5 cm2/s.
The diffusion current density is given by

=-
-
-
=

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 Drift Current

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 The above discussion shows, a steady state drift speed has
been superimposed upon the random thermal motion of the
electrons. Such a directed flow of electrons constitutes a
current.

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 Current Density

 N no of electrons are contained in a length L of a conductor. If it
takes an electron a time T (sec) to travel a distance L meter in the
conductor, the total no. of electrons passing through any cross
section of wire in unit time is N/T
 Thus the total charge per second passing any area is
I(current) = Nq/T = Nq/L
{ Since L/T is the average or drift speed v(m/s) of the electron.}
 The current density (J), current per unit area,
J = I/A = Nq/LA
 From figure, one can say that LA is the volume containing N
electrons, and so N/LA is the electron concentration density ‘n’
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  J = nq = ρ
where ρ = nq is the charge density.
 Now  = μE and J = nq
 J = nqμE = σE
where σ = nqμ is the conductivity

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 For semiconductor, we have electron and hole as
carriers, having mobility μn and μp.
 These particles move in opposite directions in an electric
field E, but they are of opposite sign, the current of each
is in the same direction.
 Hence, the current density,
J = (nμn + pμp)qE = σE
where σ = (nμn + pμp)q

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 Total Current

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 Carrier Mobility and Velocity
Mobility - the ease at which a carrier (electron
or hole) moves in a semiconductor
– Symbol: mn for electrons and mp for holes
Drift velocity – the speed at which a carrier
moves in a crystal when an electric field is
present
– For electrons: vd = mn E
– For holes: vd = mp E
 The electron in the semiconductor are moving rapidly in
all directions due to thermal energy.
The thermal motion of an individual electron may be
visualized as a succession of random scattering from
collisions with lattice atoms, impurity atoms etc.
The random motion of electrons leads to zero net
displacement of an electron over a sufficiently long
period of time.
The average distance between collisions is called the
mean free path, and the average time between
collisions is called the mean free time t.

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 In Eq. 1 the mobility is related directly to the mean free
time between collisions, which in turn is determined by
the various scattering mechanisms.
The two most important mechanisms are lattice
scattering and impurity scattering.
Lattice scattering results from thermal vibrations of the
lattice atoms at any temperature above absolute zero.
These vibrations disturb the lattice periodic potential and
allow energy to be transferred between the carriers and
the lattice.
Since lattice vibration increases with increasing
temperature, lattice scattering becomes dominant at high
temperatures; hence the mobility decreases with
increasing temperature.
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 Theoretical analysis shows that the mobility due to lattice
scattering μL will decrease in proportion to T–3/2.
Impurity scattering results when a charge carrier travels
past an ionized dopant impurity (donor or acceptor).
The charge carrier path will be deflected because of
Coulomb force interaction.
The probability of impurity scattering depends on the
total concentration of ionized impurities (the sum of the
concentration of negatively and positively charged ions).
However, unlike lattice scattering, impurity scattering
becomes less significant at higher temperatures.
At higher temperatures, the carriers move faster; they
remain near the impurity atom for a shorter time and are
therefore scattered less effectively.

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 The mobility due to impurity scattering μI can be shown
to vary as T3/2/NT, where NT is the total impurity conc.

1. The mobility depends very strongly on the temperature and on irregularities in
the crystal, which may be due to the growing of the crystal or the impurities.
2. So long as the drift velocity is less than the thermal velocity, the mobility varies
directly with, and is proportional to, the time between collisions.
3. If the drift velocity approaches the saturation velocity through an increase of the
electric field intensity, the mobility decreases with an increase of the electric field.

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 Electron mobility in silicon versus temperature for various donor
concentrations.
Inset shows the theoretical temperature dependence of electron mobility.
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 Resistivity and Conductivity
Fundamental material properties

1 1
 
q m n no  m p po  q m n  m p ni
1


 Resistivity
n-type semiconductor p-type semiconductor

Generally, in extrinsic semiconductors, only one of the components is
significant because of the many orders-of-magnitude difference
between the two carrier densities
 Find the room-temperature resistivity of an n-type silicon doped
with 1016 phosphorus atoms/cm3

ρ = 0.48 Ω-cm

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Problem:

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 Current Flow
Va Va
I  
R L 1 
 
A  q  m n no  m p po  
 
Aq  m n no  m p po 
Va
I 
L
Va
E
L
I  Aq  m n no  m p po  E
Conductivity of semiconductor

 Conductivity of intrinsic semiconductor:
σi = ni e( μe + μh)
 Conductivity of Extrinsic semiconductor:

For n – type semiconductor:
σn = n e μe = ND e μe
For p – type semiconductor:
σp = p e μh = NA e μh
Where ND and NA are the concentration of donor and
acceptor impurity.
 Generation and Recombination of charge carriers

 The photon transition is a direct, band-to-band, generation/recombination process.
 An electron from the conduction band falls back to the valence-band and releases
its energy in the form of a photon (light)  Recombination
 The reverse process, the generation of an electron-hole pair, is triggered by a
sufficiently energetic photon which transfers its energy to a valence band electron
which is excited to the conduction band leaving a hole behind.
 The photon energy for this process has to be at least of the magnitude of the band-
gap energy Eg.
 The recombination in semiconductors eliminates free
electrons and holes, setting up equilibrium in steady state.
 Recombination in semiconductors can be categorized into
two groups: radiative and non-radiative recombination.
 Non-radiative recombination mechanisms in semiconductors
are :
I. auger recombination,
II. recombination by defects, and
III. surface recombination.
 Radiative recombination occurs when an electron from the
conduction band recombines with a hole in the valence band.
 As a result of electron-hole recombination, a photon is emitted.
 Radiative recombination is the radiative transition of the
electron from the conduction band to the valence band, which
involves optical processes: a)spontaneous emission,
b)absorption or gain, and c) stimulated emission
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  In a pure semiconductor the number of holes is equal to the number
of free electrons.
 Thermal agitation, however, continues to generate g new hole-
electron pairs per unit volume per second, while other hole-electron
pairs disappear as a result of recombination;
 Free electrons fall into empty covalent bonds, resulting in the loss of a
pair of mobile carriers.
 On an average, a hole (an electron) will exist for tp(tn) sec before
recombination.
 This time is called the mean lifetime of the hole and electron,
respectively.

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 The increase in hole concentration p equals that for the electron
density n, the percentage increase for electrons in an n-type
semiconductor (where electrons are plentiful) is very small.
 On the other hand, the percentage increase in holes may be
tremendous, because holes are scarce in an n-type crystal.
 The radiation affects the majority concentration hardly at all.
 The discussion is limited to the behavior of the minority carriers.

 After a steady state is reached, at t = 0 , the radiation (external
source) is removed.
 One can show that the excess carrier density returns to zero
exponentially with time.
 For this, we must derive the differential equation which governs
the hole concentration as a function of time for t > 0 (with no
external excitation).

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8/13/2024 DR.UDAI P. SINGH 99
the excess, or injected, carrier density p’ is defined as the increase
in minority concentration above the equilibrium value. Since p’ is a
function of time, then

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 the differential equation controlling p’ is

The minus sign indicates that the change is a decrease in the
case of recombination and an increase when the
concentration is recovering from a temporary depletion
Since the radiation results in an initial (at t > 0 is

from

From Sze and Lee book
The excess carrier decreases
exponentially

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 Solution:

lnp’ = - t/tp+c1 at t=0, c1 = lnp’(0)

lnp’= -t/tp +lnp’(0)

or p’/p’(0)= e –t/tp

or p’ = p’(0) e –t/tp

8/13/2024 DR.UDAI P. SINGH 102
An N-type silicon sample is uniformly illuminated with
light which generates 1020 electron-hole pairs per cm3 per
second. The minority carrier life time in the sample is 1
microsecond. In the life steady state, the hole concentration in
the sample is approximately 10x, where x is an integer. The
value of x is ?

Answer, we know

Generation of carriers (g) = 1020 electron pairs per cm3 per second
Under steady state condition

Thereby,

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 Continuity Equation
If one disturb the equilibrium concentration of carriers in a
semiconductor material, the concentration of holes or
electrons will vary with time.
Carrier concentration in the body of a semiconductor is a
function of both time and distance.

One can derive the differential equation which governs this
functional relationship. This equation is based on the fact
that charge can neither be created not destroyed.

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 Consider the infinitesimal element of volume of area A and length dx
in (figure below) within which the average hole concentration is p.

Assume that the problem is 1D and that the hole
current Ip is a function of x. If (figure) , the current entering the
volume at x is Ip at time t and leaving at x + dx is Ip +dIp at
the same time t, there must be dIp more coulombs per
second leaving the volume than entering it (for a positive
value of dIp).

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 Hence, the decrease in number of coulombs per
second within the volume is dIp. Since the magnitude of
the carrier charge is q, then dIp/q equals the decrease in the
number of holes per second within the elemental volume A
dx. Remembering that the current density Jp = Ip / A, we have

Decrease in hole concentration (holes per

unit volume)per second, due to current Ip

Since charge can neither be created not destroyed, the increase in
holes per unit volume per second, dp/dt, must equal the
algebraic sum of all the increases listed above, or

8/13/2024 DR.UDAI P. SINGH 106
 (since both p and Jp are functions of both t and x, then partial derivatives
are used in this equation)
Continuity equation (law of conservation of charge is given
as
Increase in holes per second = Holes generated per unit
volume due to thermal generation - Holes lost per unit
volume due to recombination - Holes leaving the bar per
unit volume
OR
Rate of change of holes in dx = rate of generation &
recombination + the rate at which holes enter the small
piece less the rate at which they enter

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