2. pn Junction Diodes: I-V Characteristics
Semiconductor Device Physics
Chapter 6
pn Junction Diodes: I-V Characteristics

3. Qualitative Derivation
Chapter 6
pn Junction Diodes: I-V Characteristics
Qualitative Derivation
Majority
carriers
Majority
carriers

4. Current Flow in a pn Junction Diode
Chapter 6
pn Junction Diodes: I-V Characteristics
Current Flow in a pn Junction Diode
When a forward bias (VA > 0) is applied, the potential barrier to diffusion across the junction is reduced.
Minority carriers are “injected” into the quasi-neutral regions  Δnp > 0, Δpn > 0.
Minority carriers diffuse in the quasi-neutral regions, recombining with majority carriers.

5. Ideal Diode: Assumptions
Chapter 6
pn Junction Diodes: I-V Characteristics
Ideal Diode: Assumptions
Steady-state conditions.
Non-degenerately doped step junction.
One-dimensional diode.
Low-level injection conditions prevail in the quasi-neutral regions.
No processes other than drift, diffusion, and thermal R–G take place inside the diode.

6. Current Flow in a pn Junction Diode
Chapter 6
pn Junction Diodes: I-V Characteristics
Current Flow in a pn Junction Diode
Current density J = JN(x) + JP(x)
JN(x) and JP(x) may vary with position, but J is constant throughout the diode.
Yet an additional assumption is now made, that thermal recombination-generation is negligible throughout the depletion region  JN and JP are therefore determined to be constants independent of position inside the depletion region.

7. Carrier Concentrations at –xp, +xn
Chapter 6
pn Junction Diodes: I-V Characteristics
Carrier Concentrations at –xp, +xn
Consider the equilibrium carrier concentrations at VA = 0:
p-side
n-side
If low-level injection conditions prevail in the quasi-neutral regions when VA  0, then:

8. Chapter 6
pn Junction Diodes: I-V Characteristics
“Law of the Junction”
The voltage VA applied to a pn junction falls mostly across the depletion region (assuming that low-level injection conditions prevail in the quasi-neutral regions).
Two quasi-Fermi levels is drawn in the depletion region:

9. Excess Carrier Concentrations at –xp, xn
Chapter 6
pn Junction Diodes: I-V Characteristics
Excess Carrier Concentrations at –xp, xn
p-side
n-side

10. Example: Carrier Injection
Chapter 6
pn Junction Diodes: I-V Characteristics
Example: Carrier Injection
A pn junction has NA=1018 cm–3 and ND=1016 cm–3. The applied voltage is 0.6 V.
a) What are the minority carrier concentrations at the depletion-region edges?
b) What are the excess minority carrier concentrations?

11. Excess Carrier Distribution
Chapter 6
pn Junction Diodes: I-V Characteristics
Excess Carrier Distribution
From the minority carrier diffusion equation,
For simplicity, we develop a new coordinate system:
We have the following boundary conditions:
Then, the solution is given by:
LP : hole minority carrier diffusion length

12. Excess Carrier Distribution
Chapter 6
pn Junction Diodes: I-V Characteristics
Excess Carrier Distribution
New boundary conditions
From the x’ → ∞,
From the x’ → 0,
Therefore
Similarly,

13. pn Diode I–V Characteristic
Chapter 6
pn Junction Diodes: I-V Characteristics
pn Diode I–V Characteristic
n-side
p-side

14. pn Diode I–V Characteristic
Chapter 6
pn Junction Diodes: I-V Characteristics
pn Diode I–V Characteristic
Shockley Equation, for ideal diode
I0 can be viewed as the drift current due to minority carriers generated within the diffusion lengths of the depletion region

15. Diode Saturation Current I0
Chapter 6
pn Junction Diodes: I-V Characteristics
Diode Saturation Current I0
I0 can vary by orders of magnitude, depending on the semiconductor material, due to ni2 factor.
In an asymmetrically doped pn junction, the term associated with the more heavily doped side is negligible.
If the p side is much more heavily doped,
If the n side is much more heavily doped,

16. Diode Carrier Currents
Chapter 6
pn Junction Diodes: I-V Characteristics
Diode Carrier Currents
Total current density is constant inside the diode
Negligible thermal R-G throughout depletion region  dJN/dx = dJP/dx = 0

17. Carrier Concentration: Forward Bias
Chapter 6
pn Junction Diodes: I-V Characteristics
Carrier Concentration: Forward Bias
Law of the Junction
Low level injection conditions
Excess minority
carriers
Excess minority
carriers

18. Carrier Concentration: Reverse Bias
Chapter 6
pn Junction Diodes: I-V Characteristics
Carrier Concentration: Reverse Bias
Deficit of minority carriers near the depletion region.
Depletion region acts like a “sink”, draining carriers from the adjacent quasineutral regions

19. Deviations from the Ideal I-V Behavior
Chapter 6
pn Junction Diodes: I-V Characteristics
Deviations from the Ideal I-V Behavior
Si pn-junction Diode, 300 K.
Forward-bias current
Reverse-bias current
“Slope over”
No saturation
“Breakdown”
Smaller slope

20. Homework This time no homework. Prepare well for midterm examination.
Chapter 6
pn Junction Diodes: I-V Characteristics
Homework
This time no homework.
Prepare well for midterm examination.
Midterm examination covers material of Lecture 1 until Lecture 6.
Two A4- formula sheets may be used during exam. Formula sheets may not contain problems and solutions.
The use of calculator is allowed.
No notebooks, tablets, smart phones, nor any other electronics may be used during exam.

21. Chapter 6
pn Junction Diodes: I-V Characteristics
Exercise Problems
A certain Silicon sample is doped differently in two regions. Region A is doped with Boron (7×1016 cm–3) and Arsenic (3×1016 cm–3) while Region B only with Arsenic (1018 cm–3). At 300 K, calculate the resistance of the block.
An Si sample is given with ND = 1018 cm–3. The minority carrier lifetimes are given by 10–7 s. Holes are injected at x = 0 to generate a certain hole diffusion current density of 10 μA/cm2. Low level injection condition is assumed to be prevailed. If the hole concentration decays exponentially as x increases with a certain diffusion length constant, determine the excess concentration required to be supplied at x = 0.

22. Chapter 6
pn Junction Diodes: I-V Characteristics
Exercise Problems
A certain Si pn-junction diode is doped with NA = 2×1018 cm–3 and ND = 4×1018 cm–3. The constants are given by DN = 18 cm2/s, DP = 12 cm2/s, and τp = τn = 10–7 s.
Calculate the built-in voltage Vbi and the depletion width W at T = 300 K. Which side of the depletion layer will be wider, on the p-side or on the n-side?
Determine Jdiff if VA = 0.5 V? What is the change if VA = –0.2 V?