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© 2013 Eric Pop, UIUCECE 340: Semiconductor Electronics ECE 340 Lecture 23 Current Flow in P-N diode Last time, we talked about unbiased P-N junction.

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Presentation on theme: "© 2013 Eric Pop, UIUCECE 340: Semiconductor Electronics ECE 340 Lecture 23 Current Flow in P-N diode Last time, we talked about unbiased P-N junction."— Presentation transcript:

1 © 2013 Eric Pop, UIUCECE 340: Semiconductor Electronics ECE 340 Lecture 23 Current Flow in P-N diode Last time, we talked about unbiased P-N junction. Today, biased (V ext ≠ 0) P-N junction and current flow. Draw equilibrium (V = 0) bands: Recall built-in voltage and depletion width: 1

2 © 2013 Eric Pop, UIUCECE 340: Semiconductor Electronics Qualitative band diagrams with applied voltage: Current flow in equilibrium (V = 0): 2

3 © 2013 Eric Pop, UIUCECE 340: Semiconductor Electronics Qualitative current flow: 3

4 © 2013 Eric Pop, UIUCECE 340: Semiconductor Electronics Qualitatively expect I-V curve to be: In forward bias, inside space charge region (SCR): Where V is the applied bias and ___________________ 4

5 © 2013 Eric Pop, UIUCECE 340: Semiconductor Electronics 5 Let’s look at the injected minority carriers: On the n-side, injected holes. Just at the edge of n- side depletion region:

6 © 2013 Eric Pop, UIUCECE 340: Semiconductor Electronics Excess injected holes diffuse into the n-side: (same is true of excess injected electrons on p-side). Injected hole diffusion current: Where equilibrium hole concentration p n0 = (and similar for injected electron diffusion on p-side, just replace subscripts p with n) Hole diffusion current proportional to excess hole concentration at any distance x into the n-type region. Due to hole current continuity, we can evaluate at x=x n0 =0 6

7 © 2013 Eric Pop, UIUCECE 340: Semiconductor Electronics We can also write diffusion current for electrons in p-side: Now total current 7

8 © 2013 Eric Pop, UIUCECE 340: Semiconductor Electronics ECE 340 Lectures 24-26 P-N diode carrier injection; reverse bias & breakdown Recap diode bias diagrams: a)equilibrium b)forward bias (V > 0) c)reverse bias (V < 0) 8

9 © 2013 Eric Pop, UIUCECE 340: Semiconductor Electronics Recap some of the equations:  Depletion width (decreases at forward bias, increases at reverse bias)  Maximum electric field (decreases at forward bias, increases at reverse bias)  Built-in voltage  Charge stored 9

10 © 2013 Eric Pop, UIUCECE 340: Semiconductor Electronics  Current density (current I = J∙A )  What about an asymmetrically doped junction? Say, p side much more heavily doped (N A >> N D ): 10 Remember, current is due to minority carrier injection Typically p-n junctions in real life are made by counterdoping. E.g. start with p-type wafer and dope with N D only at the surface to obtain junction. Eqs. so far readily apply if N A = net doping on p-side = (N A – N D ) p-side N D = net doping on n-side = (N D – N A ) n-side

11 © 2013 Eric Pop, UIUCECE 340: Semiconductor Electronics Ex: a p-n junction has N A =10 19 cm -3 and N D =10 16 cm -3. The applied voltage is 0.6 V. a) What are the minority carrier concentrations at the edges of the depletion region? b) What are the excess minority carrier concentrations? c) Sketch δn(x) on the p-side if recombination lifetime is 2 μs. 11

12 © 2013 Eric Pop, UIUCECE 340: Semiconductor Electronics Current continuity along junction length, J TOT = const. As carriers recombine (deep into n- or p-side) the diffusion current is replaced by _____________ 12 But, we were able to deduce current equation by simple diffusion arguments at the _________________ where the E-field was just barely zero.

13 © 2013 Eric Pop, UIUCECE 340: Semiconductor Electronics Reverse bias:  Depletion region widens  E-field across depletion region _________________  Current is due only to minority carrier ______________ across the junction  Current is supplied by EHP generation in the __________________ (what if I change the temperature or turn on the light?)  Recall, J 0 = 13

14 © 2013 Eric Pop, UIUCECE 340: Semiconductor Electronics Junction breakdown when E-field exceeds a critical value. If current continues increasing, then diode ______________. 14

15 © 2013 Eric Pop, UIUCECE 340: Semiconductor Electronics P-N junction breakdown (3 types) 1) Zener breakdown:  Dominant for heavily doped (>10 18 cm -3 ) p + n + diodes  Breakdown at a few Volts (typically < 5 V)  Electron tunneling from filled valence states on p-side into (mostly) empty conduction band states on n-side 15

16 © 2013 Eric Pop, UIUCECE 340: Semiconductor Electronics 2) Avalanche breakdown  More lightly doped junctions (<10 17 cm -3 )  Wider depletion region, electrons accelerated across it gain enough energy to create additional EHPs  Impact ionization and carrier multiplication 16

17 © 2013 Eric Pop, UIUCECE 340: Semiconductor Electronics Empirical observation of V BR with doping and material  V BR decreases with increasing N (=N A or N D )  V BR decreases with decreasing E G 17 Breakdown dependence on temperature:  For tunneling (Zener) breakdown…  For avalanche breakdown…

18 © 2013 Eric Pop, UIUCECE 340: Semiconductor Electronics 3) Punchthrough breakdown:  Occurs when either depletion region “punches through” the entire length of the diode, e.g. x n (V) = L n 18 LnLn

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