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Dr. Nasim ZafarElectronics 1
EEE 231 – BS Electrical EngineeringFall Semester – 2012
COMSATS Institute of Information TechnologyVirtual campus
Islamabad
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Semiconductor device lab.KwangwoonUniversity Semiconductor Devices.
Junction Break Down
Lecture No: 8
Breakdown Characteristics
* Zener Breakdown
* Avalanche Breakdown
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Introduction:
• Under normal operation of a diode, an applied reverse bias (voltage) will result in a small current flow through the device.
• However, at a particular high voltage, which is called breakdown voltage VBD, large currents start to flow. If there is no current limiting resistor, which is connected in series to the diode, the diode will be destroyed. There are two physical effects which cause this breakdown.
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Breakdown Mechanism:
• Zener Effect
Occurs in heavily doping semiconductor Breakdown voltage is less than 5V Carriers generated by electric field---field ionization TC is negative
• Avalanche Effect Occurs in slightly doping semiconductor Breakdown voltage is more than 7V Carriers generated by collision TC is positive
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PN Junction Under Forward-Bias Condition:
The pn junction excited by a constant-current source supplying a current I in the forward direction. The depletion layer narrows and the barrier voltage decreases by V volts, which appears as an external voltage in the forward direction.
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Nasim Zafar 5
PN Junction Under Reverse-Bias Condition:
The pn junction excited by a constant-current source I in the reverse direction. To avoid breakdown, I is kept smaller than IS.
Note that the depletion layer widens and the barrier voltage increases by VR volts, which appears between the terminals as a reverse voltage.
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I-V Characteristic of a PN Junction:
As the reverse bias voltage increases, the electric field in the depletion region increases. Eventually, it can become large enough to cause the junction to break down so that a large reverse current flows:
breakdown voltage
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I-V Characteristic of a PN Junction:
Current increases exponentially with applied forward bias voltage, and “saturates” at a relatively small negative current level for reverse bias voltages.
pD
p
nA
niSS
VVSD
LND
LNDAqnAJI
eII TD
2
/ 1
“Ideal diode” equation:
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PN Junction Under Reverse-Bias Condition:
I-V characteristic equation:
Where Is is the saturation current, it is proportional to ni2
which is a strong function of temperature.
sIi
)(
)(
2
00
An
n
Dp
pi
n
pn
p
nps
nLD
nLD
qAn
LnD
LpD
qAI
Independent of voltage
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Breakdown Voltage VBD
One can determine which mechanism is responsible for the breakdown based on the value of the breakdown voltage VBD :
VBD < 5 V Tunneling Breakdown
VBD > 6V Avalanche Breakdown
4V < VBD < 6V both tunneling and avalanche mechanisms are responsible
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Energy Band Diagram of a PN Junction
CE
VE
FnEqV
FpE
W
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Origin of Current Flow
CE
VE
FnEqV
FpE
W
Forward bias:
CE
VEFnE
qV
FpE
W
Reverse bias:
VVq bi VVq bi
Reverse saturation current is due to minority carriers being collected over a distance of the order of the diffusion length.
Ln
Lp
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Reverse Saturation Current
The flow of these minorities produces the reverse saturation current but it is independent of applied reverse voltage.
Vb I0
VB ; Breakdown voltage
I0 ; Reverse saturation current
Forward Bias
Reverse BiasDrift current
I(current)
V(voltage)
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Ideal Diode I-V characteristic
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Real Diode I-V characteristic
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Real Diode – Reverse Current
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What’s wrong with this picture?
Reverse Bias:
– Current ~103 times larger than FB I0
– Reverse current doesn’t saturate
– Breakdown – large current above VBbd
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Avalanche Breakdown
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Avalanche Breakdown:
• Avalanche breakdown mechanism occurs when electrons and holes moving through the depletion region of a reverse biased PN junction, acquire sufficient energy from the electric field to break a bonds i.e. create electron-hole pairs by colliding with atomic electrons within the depletion region. The electric field in the depletion region of a diode can be very high.
• The newly created electrons and holes move in opposite
directions due to the electric field present within the depletion region and thereby add to the existing reverse bias current. This is the most important breakdown mechanism in PN junction.
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Avalanche BreakdownImpact Ionization Mechanism
Mechanism Total current during avalanche multiplication
In(w) = M * Ino
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Energy Band diagram; Avalanche Breakdown:
Depletion width larger than mean free path lots of collisions
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Junction Built-In Voltage:
The Junction Built-In Voltage is given as:
It depends on doping concentration and temperature
Its TC is negative.
2lni
DATo n
NNVV
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Junction Parameters:
BBR
DA
DABR
BRDA
DA
Sc
BRBRbiAbi
NV
NNNNV
VNNNN
KqE
VVVVV
1
2
0
2
One-sided junctions
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Current Density of an Avalanche Process:
dxJJ nnn dxnJ
dxJJ nnp pJ
Impact ionization initiated by electrons.
dxJJ ppn dxnJ
dxJJ ppp pJ
Impact ionization initiated by holes.
.
0,0
constJJJ
dxdJ
dxdJ
dxdJ
dxdJ
pn
pn
pn
-
Multiplication factors forelectrons and holes:
)()0(
,)0()(
WJJ
MJ
WJM
p
pp
n
nn
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Zener Breakdown
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Zener Break Down:
• Zener breakdown occurs in heavily doped p-n junctions, with a tunneling mechanism.
• The heavy doping makes the depletion layer extremely thin. So thin in fact,
carriers cannot accelerate enough to cause impact ionization.
• With the depletion layer so thin, however, quantum mechanical tunneling through the layer occurs causing the reverse current to flow.
• In a heavily doped p-n junction the conduction and valance bands on opposite side of the junction become so close during the reverse-bias that the electrons on the p-side can tunnel from directly VB into the CB on the n-side.
• The temperature coefficient of the Zener mechanism is negative, the breakdown voltage for a particular diode decreases with increasing temperature.
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Semiconductor Devices
Zener Breakdown Mechanism:
xe-h+
P nEc
Ec
Ev
Ev
Ef
EfZener effect
Doping level > 1018/Cm3
Highly Doped Junction ( narrow W)
Mechanism is termed Tunneling or Zener Breakdown
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Tunneling Breakdown:• Tunneling breakdown occurs in heavily-doped p-n
junctions in which the depletion region width W is about 10 nm.
W
EF
EC
EV
Zero-bias band diagram: Forward-bias band diagram:
W
EFn
EC
EV
EFp
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Visualization of Tunneling:
Barrier must be thin: depletion is narrow doping on both sides must be large
Must have empty states to tunnel into Vbi + VBR > EG/q
2
1
02
applbi
AD
DAS VVNNNN
qKW
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Zener Diode Characteristics
IZK=
IZT=
IZM=
Zener kneecurrent
Zener testcurrent
MaximumZener current
IR
VRVZ
IF
VF
RVSIR
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Zener Diode Characteristics:
•The breakdown characteristics of diodes can be tailored by controlling the doping concentration
Heavily doped p+ and n+ regions result in low breakdown voltage (Zener effect)
Used as reference voltage in voltage regulators
I
VRegion of operation
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Example: Zener diode.
A 1N754A Zener diode has a dc power dissipation rating of 500 mW and a nominal Zener voltage of 6.8 V. What is the value of IZM for the device?
(max) 500mW 73.5mA6.8V
DZM
Z
PI
V
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Summary