Transcript Document

Integrated Circuit Devices
Professor Ali Javey
Summer 2009
PN Junctions
Reading: Chapter 5
PN Junctions
Donors
N-type
P-type
– V +
I
I
N
P
V
Reverse bias
Forward bias
diode
symbol
A PN junction is present in every semiconductor device.
Energy Band Diagram and Depletion Layer of a PN Junction
N-region
P-region
Ef
(a)
Ec
(b)
Ec
Ef
Ev
Ev
Ec
Ef
Ev
(c)
Neutral
N-region
Depletion
layer
Neutral
P-region
Ec
(d)
Ef
Ev
A depletion layer
exists at the PN
junction. n  0 and
p  0 in the
depletion layer.
Doping Profile of “Idealized Junctions”
p
n
p
n
Qualitative Electrostatics
Band diagram
Built in-potential
From e=-dV/dx
Formation of pn junctions
When the junction is formed, electrons from the n-side and holes
from the p-side will diffuse leaving behind charged dopant atoms.
Remember that the dopant atoms cannot move! Electrons will
leave behind positively charged donor atoms and holes will leave
behind negatively charged acceptor atoms.
The net result is the build up of an electric field from the positively
charged atoms to the negatively charged atoms, i.e., from the nside to p-side. When steady state condition is reached after the
formation of junction (how long this takes?) the net electric field
(or the built in potential) will prevent further diffusion of electrons
and holes. In other words, there will be drift and diffusion currents
such that net electron and hole currents will be zero.
Equilibrium Conditions
Under equilibrium conditions, the net electron current and hole current will
be zero.
E-field
N-type
P-type
NA = 1017 cm3
ND = 1016 cm3
hole diffusion current
net current = 0
hole drift current
Built-in Potential
N-region
n  Nd  Nce
 q A kT
kT N c
 A
ln
q
Nd
2
ni
kT N c N a
 q B kT
P-region n 
 Nce
B
ln
2
Na
q
ni
Nc
kT  N c N a

Vbi  B  A 
ln
 ln
2

q 
Nd
ni




Ec
qVbi
Ef
(b)
kT N d N a
Vbi 
ln
2
q
ni
qB
qA
Ev
The Depletion Approximation
We assume that the free carrier
concentration inside the depletion
region is zero.
We assume that the charge density
outside the depletion region is zero
and q(Nd-Na) inside the depletion.
a)
b)
Field in the Depletion Layer
N
Nd
N eut ra l Re gion
N
P
Na
D eple tion L a yer
–xn
N e utral R egi on
P
xp
0
d E   qN a
es
dx

qNd
xp
c)
–xn
E ( x) 
x
E ( x) 
 bi
es
( x p  x)
On the N-side,  = qNd
 E
–xn
qN a
–qN a
)
)
On the P-side of the
depletion layer,  = –qNa
xp
0
V
x
qN d
es
( x + xn )
(a)
(b)
Field in the Depletion Layer
N
Nd
N eut ra l Re gion
N
P
Na
D eple tion L a yer
–xn
N e utral R egi on
P
xp
0

The electric field is continuous at x = 0.
qNd
(c)
–xn
Naxp = Ndxn
xp
x
–qN a
A one-sided junction is called
a N+P junction or P+N junction

(d)
Depletion Width
EXAMPLE: A P+N junction has Na=1020 cm-3 and Nd
=1017cm-3. What is a) its built in potential, b)Wdep , c)xn ?
Solution:
a)
b)
kT N d N a
1020 1017 cm6
bi 
ln
 0.026V ln
1V
2
20
6
q
10 cm
ni
Wdep
c)
1/ 2
2e sbi  2 12 8.8510 1 


 
19
17
qNd
 1.6 10 10

14
xn  Wdep  0.12 μm
 0.12 μm
Reverse-Biased PN Junction
Forward Biased PN Junction
Junction Breakdown
I
Forward Current
V B, breakdown
voltage
V
Small leakage
Current
A Zener diode is designed to operate in the breakdown mode.
Quantum Mechanical Tunneling
Potential energy barrier
E
d
x
Tunneling Breakdown
(a)
Ec
Ef
Ev
(b)
Filled States -
Empty States
Ec
Ev
I
(c)
V
Breakdown
Dominant breakdown
cause when both sides of a
junction are very heavily
doped.
Avalanche Breakdown
Ec
original
electron
impact ionization
Efp
Ev
avalanche breakdown
electron-hole
pair generation
Ec
Efn
The PN Junction as a Temperature Sensor
I  I 0 (eqV kT 1)
 Dp
Dn 

I 0  Aqni
+
L N

 p d Ln N a 
2
What causes the IV curves to shift to lower V at higher T ?
Other PN Junction Devices–From Solar Cells to
Laser Diodes
Solar Cells
Also known as
photovoltaic cells,
solar cells can
convert sunlight
to electricity with
15-30% energy
efficiency
Solar Cells
short circuit
light
N
I
P
-
Dark IV
Eq.(4.9.4)
Isc
Ec
Ev
+
–Isc
(a)
0.7 V
0
V
Solar Cell
IV
Eq.(4.12.1)Maximum
power-output
(b)
p-i-n Photodiodes
•Only electron-hole pairs generated
in depletion region (or near
depletion region) contribute to
current
•Only light absorbed in depletion
region contributes to generation
–Stretch depletion region
–Can also operate near avalanche
to amplify signal
Light Emitting Diodes (LEDs)
•LEDs are typically made of
compound semiconductors
–Why not Si