pn junction diode: i-v characteristics · 2018. 1. 30. · chapter 6. pn junction diode : i-v...
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Chapter 6. PN Junction Diode : I-V Characteristics
PN Junction Diode: I-V Characteristics
Sung June [email protected]
http://helios.snu.ac.kr
Chapter 6.
Chapter 6. PN Junction Diode : I-V Characteristics
Contents
q Qualitative Derivation
q Quantitative Solution Strategy
q Quasineutral Region Considerations
q Depletion Region Considerations
q Boundary Conditions
2
Chapter 6. PN Junction Diode : I-V Characteristics
q The Ideal Diode Equation
• Qualitative Derivationü Equilibrium situation
ü The I-V characteristics of the ideal diode are modeled by the ideal diode equation à qualitative and quantitative derivation
potentialhill
high-energy carrierdiffusiondrift
balance
E
Chapter 6. PN Junction Diode : I-V Characteristics
ü Forward bias situation à a lowering of the potential hill
ü The same number of minority carriers are being swept
ü More majority carriers can surmount the hill à IN and IPà Iü The number of carriers that have sufficient energy to surmount the barrier goes up exponentially with VA à
exponential increase of the forward current
Chapter 6. PN Junction Diode : I-V Characteristics
ü The barrier increase reduces the majority carrier diffusion to a negligible levelü The p-side electrons and n-side holes can wander into the depletion region and be swept to the other side àreverse I (nàp)
ü Reverse bias situation à an increase of the potential hill
ü Being associated with minority carriers, the reverse bias current is expected to be extremely small
Chapter 6. PN Junction Diode : I-V Characteristics
ü The minority carrier drift currents are not affected by the height of the hill (The situation is similar to a waterfall)ü If the reverse bias saturation current is taken to be –I0, the overall I-Vdependence is
I-V characteristic
A ref/0 ( 1)V VI I e= -
Rectification
qkTVref =
Chapter 6. PN Junction Diode : I-V Characteristics
ü Whenever an electron on the p-side moves to the n-side, it is replaced by an electron generated through one of the R-G centers
ohmic
ohmicminority
minority
excess majority carriers à local
excess majority carriers à local E
E
Excess carriers move to the contact with a relaxation time à greatly fast
recombination
ü Current componentDepletion region : electrons and holesp-region (far) : holesn-region (far) : electrons
Chapter 6. PN Junction Diode : I-V Characteristics
• Quantitative Solution Strategyü Basic assumptions
(1) Steady state conditions(2) A nondegenerately doped step junction(3) One-dimensional(4) Low-level injection(5) GL=0
N P( ) ( )J J x J x= +
N n N
P p P
dnJ qu n qDdxdpJ qu p qDdx
= +
= +
E
E
AJI =
Chapter 6. PN Junction Diode : I-V Characteristics
• Quasineutral Region Considerations
2p p p
N L2n
2n n n
P L2p
n n nD G
t xp p pD Gt x
t
t
¶D ¶ D D= - +
¶ ¶
¶D ¶ D D= - +
¶ ¶
2p p
N p2n
2n n
P n2p
0 . . .
0 . . .
d n nD x x
dxd p pD x xdx
t
t
D D= - £ -
D D= - ³
and low-level injection à minority carrier diffusion equations0@E
Chapter 6. PN Junction Diode : I-V Characteristics
ü Since and dn0/dx=dp0/dx=0 in the quasineutral regions0@E
pN N p
nP P n
. . .
. . .
d nJ qD x x
dxd pJ qD x xdx
D= £ -
D= - ³
0 p
0 n
n n np p p
= + D
= + D
Q
ü We can only determine JN(x) in the quasineutral p-region and JP(x) in the quasineutral n-region• Depletion Region Considerations
N P
thermal thermalR G R G
1 10 , 0dJ dJn pq dx t q dx t
- -
¶ ¶= + = - +
¶ ¶
processesotherGRthermalP
processesotherGRthermalN
tp
tpJ
qtp
tn
tnJ
qtn
¶¶
+¶¶
+×Ñ-=¶¶
¶¶
+¶¶
+×Ñ=¶¶
-
-
1
1
Chapter 6. PN Junction Diode : I-V Characteristics
ü Suppose that thermal recombination-generation is negligible throughout the depletion region;ü à JN and JP are constants inside the depletion region
thermal R-G thermal R-G/ | / | 0n t p t¶ ¶ = ¶ ¶ =/ 0 and / 0N PdJ dx dJ dx= =
N p n N p
P p n P n
( ) ( )
( ) ( )
J x x x J xJ x x x J x
- £ £ = -
- £ £ =
N p P n( ) ( )J J x J x= - +
Chapter 6. PN Junction Diode : I-V Characteristics
• Boundary Conditionsü At the Ohmic Contacts
The ideal diode is usually taken to be a “wide-base” diodeThe contacts may effectively be viewed as being positioned at x= ±¥
ü At the Depletion Region EdgesUnder nonequilibrium conditions:
Equilibrium conditions Nonequilibrium conditions
( )( ) 0
0
=+¥®D
=-¥®D
xpxn
n
p
( ) ( ) kTFEi
kTEFi
piiN enpenn // , -- ==
Chapter 6. PN Junction Diode : I-V Characteristics
nL� pL�N P( ) /2 F F kT
inp n e -=
A /2p n. . .qV kT
inp n e x x x= - £ £
A
FpFPN
qV
EEFFN
=
-£-
If the equal signal is assumed to hold throughout the depletion region
: law of junction
Chapter 6. PN Junction Diode : I-V Characteristics
ü Evaluating the equation at the p-edge
A /2p p p A i( ) ( ) ( ) qV kTn x p x n x N n e- - = - =
A
2/i
pA
( ) qV kTnn x eN
- =
A
2/i
p pA
( ) ( 1)qV kTnn x eN
D - = -
ü Similarly,
Chapter 6. PN Junction Diode : I-V Characteristics
A
2/i
n nD
( ) ( 1)qV kTnp x eN
D = -
Chapter 6. PN Junction Diode : I-V Characteristics
• Derivation Properü The origin of coordinates is shifted to the n-edge of the depletion region
2'n n
P '2p
0 . . . 0d p pD xdx tD D
= - ³
'n ( ) 0p xD ® ¥ =
A
2/' i
nD
( 0) ( 1)qV kTnp x eN
D = = -
ü Boundary conditions
ü The general solution
P P'/ '/'n 1 2
'
( )
. . . 0
x L x Lp x Ae A ex
-D = +
³ P P pL D t=Q
Chapter 6. PN Junction Diode : I-V Characteristics
ü A2 à 0 because exp(x’/Lp) à ¥ as x’ à ¥ü With , A1=Dpn(x’=0)
A P
2/ '/' 'i
nD
( ) ( 1) . . . 0qV kT x Lnp x e e xN
-D = - ³
A P
2/ '/' 'n P i
P P 'P D
( ) ( 1) . . . 0qV kT x Ld p D nJ x qD q e e xdx L N
-D= - = - ³
ü On the p-side of the junction with the x’’-coordinate.
NA
2"//" "i
pA
( ) ( 1) . . . 0x LqV kTnn x e e xN
-D = - ³
NA
2p "//" "N i
N N "N A
( ) ( 1) . . . 0x LqV kTd n D nJ x qD q e e xdx L N
-D= - = - ³
Chapter 6. PN Junction Diode : I-V Characteristics
ü The current densities at the depletion region edges,
A
2/" N i
N p NN A
( ) ( 0) ( 1)qV kTD nJ x x J x q eL N
= - = = = -
A
2/' P i
P n PP D
( ) ( 0) ( 1)qV kTD nJ x x J x q eL N
= = = = -
A
2 2/N i P i
N A P D
( 1)qV kTD n D nI AJ qA eL N L N
æ ö= = + -ç ÷
è ø
A /0
2 2N i P i
0N A P D
( 1)qV kTI I e
D n D nI qAL N L N
= -
æ öº +ç ÷
è ø
Ideal diode equation or Shockley equation
Chapter 6. PN Junction Diode : I-V Characteristics
• Examination of Results
Chapter 6. PN Junction Diode : I-V Characteristics
ü Carrier currentsü The total current density is constantü The majority-carrier current densities are obtained by graphically subtracting the minority-carrier current densities from the total current density
Chapter 6. PN Junction Diode : I-V Characteristics
ü Carrier concentrationsü Forward biasing increases the concentration
Reverse decreases
ü Under the low-level injection, the majority carrier concentrations in these regions are everywhere approximately equal to their equilibrium values
Chapter 6. PN Junction Diode : I-V Characteristics
ü Under reverse biasing the depletion region acts like a “sink” for minority carriersü Larger reverse biases have little effect
NA > ND
Chapter 6. PN Junction Diode : I-V Characteristics
6.2.2 Reverse-Bias Breakdown
Chapter 6. PN Junction Diode : I-V Characteristics
q Zener Process• Tunneling
– The particle energy remains constant during the process.ü The particle and the barrier are not damaged.
(1) There must be filled states on one side and empty states on the other side at the same energy.
(2) d must be very thin.
Chapter 6. PN Junction Diode : I-V Characteristics
Reverse bias↑ ⇒ # of filled valence electrons placed opposite empty conduction-band states↑ ⇒ current↑
6.2.3 The R-G Currentü A current far in excess of that predicted by the ideal theory exists
at small forward bias and all reverse biases.← thermal recombination-generation in the depletion region
Chapter 6. PN Junction Diode : I-V Characteristics
Ec
Ef
Ev
Ec
Ef
Ev
VR
IR
VR = 0 V (Equilibrium)
Chapter 6. PN Junction Diode : I-V Characteristics
Ec
Ef
Ev
Ec
Ef
Ev
VR
IR
h+
VR < 0 VVR = 0 V
e-
Chapter 6. PN Junction Diode : I-V Characteristics
VR
IR
Ec
Ef
Ev
Ec
Ef
Ev
e-
e-e-
e-e-
VR << 0 V (Zener Breakdown, Tunneling)VR = 0 V
Chapter 6. PN Junction Diode : I-V Characteristics
ü Reverse bias ⇒ , ⇒ thermal generation ü Forward bias ⇒ , ⇒ recombination(1) The net R-G rate is the same for electrons and holes.(2) For every electron-hole pair created or destroyed per second, one
electron per second flows into or out of the diode contacts.
0nn < 0pp <0nn > 0pp >
Chapter 6. PN Junction Diode : I-V Characteristics
GRDIFF
kTEEn
kTEEp
in
ip
iGR
x
xnp
iGR
np
i
GRthermal
GRthermal
x
xGR
III
eenp
nn
WqAnI
pn
dxppnn
nnpqAI
ppnnnnp
tn
dxtnqAI
TiiT
n
p
n
p
-
--
-
--
-
---
+=
+=+º
-=
®®
+++-
=
+++-
-=¶¶
¶¶
-=
ò
ò
)(21)(
21
2
0,0
)()(
)()(
/)(/)(110
0
11
2
11
2
ttttt
t
tt
tt kTEEi
kTEEi
Ti
iT
enp
enn/)(
1
/)(1
-
-
º
º
Chapter 6. PN Junction Diode : I-V Characteristics
Summary
31
Chapter 6. PN Junction Diode : I-V Characteristics
Summary
32