Avalanche breakdown. Impact ionization causes an avalanche of current. Occurs at low doping

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1 Avalanche breakdown Impact ionization causes an avalanche of current Occurs at low doping

2 Zener tunneling Electrons tunnel from valence band to conduction band Occurs at high doping

3 Tunneling wave decays exponentially in the classically forbidden region e 1 >e 2 Tunneling is a wave phenomena. Tunneling and total internal reflection are used in a beam splitter.

4 Zener tunneling Breakdown voltage is typically much lower than the breakdown voltage of an avalanche diode and can be tuned by adjusting the width of the depletion layer. Used to provide a reference voltage.

5 Avalanche breakdown Tunneling

6 Technische Universität Graz Institute of Solid State Physics metal - semiconductor contacts Photoelectric effect Workfunction Electron affinity Interface states Schottky barriers Schottky diodes Ohmic contacts Thermionic emission Tunnel contacts

7 Photoelectric effect hf 0 = ef at threshold current workfunction f threshold frequency f 0

8 Singh There is a dipole field at the surface of a metal. This electric field must be overcome for an electron to escape.

9 work function - electron affinity If f s < f m, the semiconductor bands bend down. If f s > f m, the semiconductor bands bend up.

10 work function - electron affinity Electrons flow from a low work function material to high work function material. The high work function material becomes negatively charged. You have to push the electrons uphill into the low work function material. This determines the band bending. If f s < f m, the semiconductor bands bend down. If f s > f m, the semiconductor bands bend up.

11 Singh

12

13 p-type Walter Schottky Schottky contact / ohmic contact E F,m metal E F,s Schottky contact E F,m metal E F,s Ohmic contact: linear resistance specific contact resistance: R c J V 1 -cm 2

14 n-type Schottky contact / ohmic contact E F,s Schottky contact E F,m metal E F,m metal E F,s Ohmic contact: linear resistance specific contact resistance: R c J V 1 -cm 2

15 Interface states

16

17 Schottky barrier V f f bi s m en D E x xn e re 0 W x n 2e Vbi en V D 2 en D x V xxn 0 x x e 2 n Like a one sided junction, the metal side is heavily doped.

18 CV measurements x p 2e Vbi en V A e ee N A C x 2 V V p bi -2 F m 2 2 V 1 bi C ee N V A 1/C 2 V GaAs has larger E g and V bi

19 Thermionic emission 1901 Richardson Owen Willans Richardson Current from a heated wire is: J A 2 RT exp ef kbt Some electrons have a thermal energy that exceeds the work function and escape from the wire.

20 diode Vacuum diodes

21 Thermionic emission Fermi function e V bi V E F EF E E F E E f ( E) exp exp exp exp kbt kbt kbt kbt The density of electrons with enough energy to go over the barriers E exp kbt

22 Thermionic emission n th ev exp kbt I sm ev nth exp kbt I ( 0) ms I sm V ev B I I e k T sm Ims I s 1

23 Schottky barrier I I sm > I sm ~ 0 ms I ms constant

24 Thermionic emission ev B I I e k T sm Ims I s 1 Nonideality factor = 1

25 Thermionic emission I s * ef 2 b AART exp kbt A = Area A R* = Richardson constant n-si A * R = 110 A K -2 cm -2 p-si A * R = 32 A K -2 cm -2 n-gaas A * R = 8 A K -2 cm -2 p-gaas A * R = 74 A K -2 cm -2 Thermionic emission dominates over diffusion current in a Schottky diode.

26 Schottky diodes Majority carrier current dominates. nonideality factor = 1. Fast response, no recombination of electron-hole pairs required. Used as rf mixers. Low turn on voltage - high reverse bias current ev B I I e k T s 1

27 Tunnel contacts For high doping, the Schottky barrier is so thin that electrons can tunnel through it. metal p+ p Degenerate doping at a tunnel contact metal n+ n Tunnel contacts have a linear resistance.

28 Contacts

29 Transport mechanisms Drift Diffusion Thermionic emission Tunneling All mechanisms are always present. One or two transport mechanisms can dominate depending on the device and the bias conditions. In a forward biased pn-junction, diffusion dominates. In a tunnel contact, tunneling dominates. In a Schottky diode, thermionic emission dominates.

30 Technische Universität Graz Institute of Solid State Physics JFETs - MESFETs - MODFETs Junction Field Effect Transistors (JFET) Metal-Semiconductor Field Effect Transistors (MESFET) Modulation Doped Field Effect Transistors (MODFET) n

31 JFET n-channel JFET n For N A >> N D 2 ( ) x n e Vbi V en D Depletion mode h x n 2eV bi en D conducting at V g = 0 Enhancement mode h x n 2eV bi en D nonconducting at V g = 0

32 Power SiC JFET p n p

33 depletion zone n-channel (power) JFET

34 n-channel JFET drain p+ n+ depletion region p n p gate n+ source JFETs are often discrete devices

35 MESFET Metal-Semiconductor Field Effect Transistors n Depletion layer created by Schottky barrier x n 2 e ( Vbi V ) en D Fast transistors can be realized in n-channel GaAs, however GaAs has a low hole mobility making p-channel devices slower.

36 JFET n D n-channel JFET D G S n-channel JFET x n 2 e ( Vbi V ) en D G S p-channel JFET 2 Pinch-off at h = x en n Dh Vp 2e V p = pinch-off voltage At Pinch-off, V p = V bi - V.

37 The drain is the side of the transistor that gets pinched off. JFET

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