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Chapter 5. pn Junction Electrostatics. Metallurgical Junction. Doping profile. Step junction idealization. Chapter 5. pn Junction Electrostatics. Poisson’s Equation. Poisson’s equation is a well-known relationship in electricity and magnetism. - PowerPoint PPT Presentation
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President University Erwin Sitompul SDP 5/1
Dr.-Ing. Erwin SitompulPresident University
Lecture 5Semiconductor Device Physics
http://zitompul.wordpress.com
President University Erwin Sitompul SDP 5/2
Step junctionidealization
Metallurgical JunctionChapter 5 pn Junction Electrostatics
Doping profile
President University Erwin Sitompul SDP 5/3
Poisson’s EquationChapter 5 pn Junction Electrostatics
S 0K
E v DD E
S 0K
S 0x K
E
Poisson’s equation is a well-known relationship in electricity and magnetism.
It is now used because it often contains the starting point in obtaining quantitative solutions for the electrostatic variables.
In one-dimensional problems, Poisson’s equation simplifies to:
President University Erwin Sitompul SDP 5/4
Equilibrium Energy Band DiagramChapter 5 pn Junction Electrostatics
pn-Junction diode
President University Erwin Sitompul SDP 5/5
Band diagram
c ref1 ( )V E Eq
Qualitative ElectrostaticsChapter 5 pn Junction Electrostatics
Equilibrium condition
Electrostatic potential
( )V x dxE
President University Erwin Sitompul SDP 5/6
Electric field
Qualitative ElectrostaticsChapter 5 pn Junction Electrostatics
Equilibrium condition
Charge density
dVdx
E
S 0K
Ex
S 0
( )x xK
E
President University Erwin Sitompul SDP 5/7
Formation of pn Junction and Charge DistributionChapter 5 pn Junction Electrostatics
D A( )q p n N N qNA– qND
+
President University Erwin Sitompul SDP 5/8
Formation of pn Junction and Charge DistributionChapter 5 pn Junction Electrostatics
President University Erwin Sitompul SDP 5/9
DF i n-side
i i
( ) ln ln NnE E kT kTn n
bi F i n side i F p side( ) ( )qV E E E E
Ai F p-side
i i
( ) ln ln NpE E kT kTn n
A Dbi 2
i
ln N NqV kTn
Built-In Potential Vbi
Chapter 5 pn Junction Electrostatics
For non-degenerately doped material,
• Vbi for several materials:Ge ≤ 0.66 VSi ≤ 1.12 VGeAs ≤ 1.42 V
President University Erwin Sitompul SDP 5/10
A1
S
( ) qNx x c
E
A
S
qNddx
E
Dn
S
( ) ( )qNx x x
E
Ap
S
( ) ( )qNx x x
Ewith boundary E(–xp) 0
with boundary E(xn) 0
The Depletion ApproximationChapter 5 pn Junction Electrostatics
On the p-side, ρ = –qNA
On the n-side, ρ = qND
President University Erwin Sitompul SDP 5/11
A p
D n
, 0 , 0 0,
qN x xqN x x
otherwise
Ap p
S
Dn n
S
( ), 0( )
( ), 0
qN x x x xx qN x x x x
E
2Ap p
S
2Dbi n n
S
( ) , 02( )
( ) , 02
qN x x x xV x qNV x x x x
Step Junction with VA 0Chapter 5 pn Junction Electrostatics
Solution for ρ
Solution for E
Solution for V
President University Erwin Sitompul SDP 5/12
2 2A Dp bi n
S S
( ) ( )2 2qN qNx V x
A p D nN x N x
Step Junction with VA0Chapter 5 pn Junction Electrostatics
At x = 0, expressions for p-side and n-side for the solutions of E and V must be equal:
President University Erwin Sitompul SDP 5/13
Relation between ρ(x), E(x), and V(x)Chapter 5 pn Junction Electrostatics
1.Find the profile of the built-in potential Vbi
2.Use the depletion approximation ρ(x) With depletion-layer widths xp, xn unknown
3.Integrate ρ(x) to find E(x) Boundary conditions E(–xp) 0, E(xn)0
4.Integrate E(x) to obtain V(x) Boundary conditions V(–xp) 0, V(xn) Vbi
5.For E(x) to be continuous at x 0, NAxp NDxnSolve for xp, xn
President University Erwin Sitompul SDP 5/14
S An bi
D A D
2( )
Nx Vq N N N
S Dp bi
A A D
2( )
Nx Vq N N N
n px x W
Dn
A
N xN
Depletion Layer WidthChapter 5 pn Junction Electrostatics
Eliminating xp,
Eliminating xn,
Summing Sbi
A D
2 1 1 Vq N N
Exact solution, try to derive
President University Erwin Sitompul SDP 5/15
S bi Dn p n
D A
2 , 0V NW x x xq N N
S bi2 VW
q N
S bi Ap n p
A D
2 , 0V NW x x xq N N
One-Sided JunctionsChapter 5 pn Junction Electrostatics
If NA >> ND as in a p+n junction,
If ND >> NA as in a n+p junction,
Simplifying,
where N denotes the lighter dopant density
President University Erwin Sitompul SDP 5/16
D Abi 2
i
ln N NkTVq n
S bi
D
2 VW
qN
n 0.115 mx W
Dp n
A
Nx xN
Example: Depletion Layer WidthChapter 5 pn Junction Electrostatics
A p+n junction has NA 1020 cm–3 and ND 1017cm–3, at 300 K.
a) What isVbi?
b) What is W?
c) What is xn?
d) What is xp?
17 20
10 2
10 1025.86 mV ln 1.012 V(10 )
1/ 214
19 17
2 11.9 8.854 10 1.012 0.115 m1.602 10 10
30.115 m 10 1.15 Å
President University Erwin Sitompul SDP 5/17
Step Junction with VA 0Chapter 5 pn Junction Electrostatics
• To ensure low-level injection conditions, reasonable current levels must be maintained VA should be small
President University Erwin Sitompul SDP 5/18
Step Junction with VA 0Chapter 5 pn Junction Electrostatics
In the quasineutral, regions extending from the contacts to the edges of the depletion region, minority carrier diffusion equations can be applied since E ≈ 0.
In the depletion region, the continuity equations are applied.
President University Erwin Sitompul SDP 5/19
A Dbi
i i
ln lnN NkT kTVq n q n
Sp n bi A
A D
2 1 1W x x V Vq N N
S Dp bi A
A A D
2 ,Nx V Vq N N N
S A
n bi AD A D
2 Nx V Vq N N N
Step Junction with VA 0Chapter 5 pn Junction Electrostatics
Built-in potential Vbi (non-degenerate doping):
A D2
i
ln N NkTq n
Depletion width W :
,Dp
A D
Nx WN N
WNN
NxDA
An
President University Erwin Sitompul SDP 5/20
Effect of Bias on ElectrostaticsChapter 5 pn Junction Electrostatics
• If voltage drop â, then depletion width â• If voltage drop á, then depletion width á
President University Erwin Sitompul SDP 5/21
Linearly-Graded JunctionChapter 5 pn Junction Electrostatics
S
1 dx
E V dx E
President University Erwin Sitompul SDP 5/22
1. (6.4)Consider a silicon pn junction at T = 300 K with a p-side doping concentration of NA 1018 cm–3. Determine the n-side doping concentration such that the maximum electric field is |Emax| 3×105 V/cm at a reverse bias voltage of VR 25 V.
Chapter 5 pn Junction Electrostatics
Homework 4
Deadline: Wednesday,16 May 2012, at 14:00.
2. (7.6)Problem 5.4Pierret’s “Semiconductor Device Fundamentals”.
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