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ECEE 302: Electronic Devices

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1 ECEE 302: Electronic Devices
28 October 2002 ECEE 302: Electronic Devices Lecture 4. Effect of Excess Carriers in Semi-Conductors 28 October 2002

2 Outline Optical Absorption Luminescence
Photo-Luminenscence Cathodoluminescence Electroluminescence Carrier Lifetime and Photoconductivity Direct Re-Combination of electrons and holes Indirect Combination; Trapping Steady State Carrier Generation: Quasi-Fermi Levels Photoconductive Devices Diffusion of Carriers Diffusion Process Diffusion and Drift of Carriers, (built in fields) Continuity Equation (Diffusion and Recomination) Steady State Carrier Injection and Diffusion Length Haynes-Shockley Experiment Gradients in the Quasi-Fermi levels 28 October 2002

3 Optical Absorption Optical Absorption Process Text, Figure 4-1
Absorption Experiment Text, Figure 4-2 & 4-3 Band Gaps of common semi-conductors Text, Figure 4-4 28 October 2002

4 Luminescence Luminescence refers to light emission from solids
Types of Luminescence Photoluminescence Text, Figures 4-5 & 4-6 Direct excitation and recombination of an EHP Trapping Color is determined by impurities that create different energy levels within the solid Florescence fast luminescence process Phosphorescence (phosphors) slow luminescence process mulitple trapping process Electroluminescence mechanism for LEDs electric current causes injection of minority carriers to regions where they combine with majority carriers to produce light 28 October 2002

5 Example: Absorption (Example 4-1) (1 of 2)
Problem: GaAs with t=.46mm. Illumination=monochromatic light =hn=2eV, a=5x104 cm-1. Pincident=10mW (a) Find the total energy absorbed by the sample per sec (J/s) (b) Find the rate of excess thermal energy given up to the electrons in the lattice prior to recombination (J/s) (c) Find the number of photons per second given off from recombination events (assume 100% quantum efficiency) 28 October 2002

6 Example: Absorption (Example 4-1) (2 of 2)
28 October 2002

7 Carrier Lifetime and Photoconductivity
Excess electrons and holes increase conductivity of semi-conductors When excess carriers are produced from optical luminescence, the resulting increase in conductivity is called photoconductivity This is the primary mechanism in the operation of solar cells Mechanisms Direct Recombination Text, Figure 4- 7 Indirect Recombination, Trapping Text, Figure 4- 8 Impurity Energy Levels Text, Figure 4- 9 Photo-conductive decay Text, Figure 4-10 Steady State Carrier Generation; Quasi-Fermi Levels Text, Fig 4-11 Photo-conductive Devices 28 October 2002

8 Direct Recombination of Electrons and Holes (1 of 2)
Direct Recombination of an electron and hole occurs spontaneously 28 October 2002

9 Direct Recombination of Electrons and Holes (2 of 2)
28 October 2002

10 Steady State Carrier Generation
28 October 2002

11 Example 4-2 (Textbook, Page 121)
28 October 2002

12 Quasi-Fermi Levels Fermi Level is valid only when there are no excess carriers present We define the “quasi-Fermi” level for electrons (Fn) and holes (Fp) to describe steady state carrier concentrations Excess Electrons Excess Holes ECONDUCTION Fn EFERMI Fp EVALANCE 28 October 2002

13 Example, Text page 122 28 October 2002

14 Optical Sensitivity of a Photo conductor
Photo-conductors are conductors that change their conductivity when illuminated by light Applications are electric eyes, exposure meters for photography, solar cells, etc Sensitivity to specific light color (frequency) is determined by the energy gap 28 October 2002

15 Diffusion of Carriers Diffusion Process Text, Figure 4-12 & 4-13
motion of carriers from high density to low density states Diffusion and Drift - Built in Fields Text, Figure 4-14 & 15 Continuity Equation (Diffusion and Recombination) Text, Fig 4-16 Steady State Carrier Injection (Diffusion Length) Text, Fig 4-17 Haynes-Shockley Experiment Text, Figure 4-18 & 4-19 Gradients in the Quasi-Fermi Levels 28 October 2002

16 Clustered Group of Particles Uniformly Distributed Group of Particles
Diffusion Process Diffusion refers to the process of particles moving from areas of high density to areas of low density The diffusion rate is driven by the concentration at a point Before Clustered Group of Particles After Uniformly Distributed Group of Particles 28 October 2002

17 Diffusion Equation (1 of 2)
L n1 n2 L L x0 n1 >n2 28 October 2002

18 Diffusion Equation (2 of 2) Particles and Current
28 October 2002

19 Diffusion and Drift of Carriers
Forces that can cause electron (hole) drift are Diffusion - driven by carrier concentration Electro-Motive Force - driven by an Electric Field (F=qE) 28 October 2002

20 Built in Electric Fields
28 October 2002

21 Einstein Relationship
28 October 2002

22 Example, Text page 130 EC n(x) E(x) N0 EF Ei EV ni x x 28 October 2002

23 Continuity Equation 28 October 2002

24 Diffusion Length: Steady State Carrier Injection
28 October 2002

25 Diffusion Length 28 October 2002

26 Haynes-Shockley Experiment
The Haynes-Shockley Experiment results in the independent determination of minority carrier mobility (m) and the minority carrier diffusion constant (D) 28 October 2002

27 Example, Text Page 28 October 2002

28 Gradients in the Quasi-Fermi Levels
Equilibrium implies no gradient in the Fermi level Combination of drift (due to Electric Field) and diffusion implies there is a gradient in the “quasi” Fermi Level 28 October 2002

29 Summary We described methods of calculating carrier concentrations under equilibrium conditions in the previous lecture This lecture we discussed carrier concentrations under non-equilibrium conditions Mechanisms (Optical Absorption-Direct and Indirect Recombination) Quasi-Fermi Levels to describe non-equilibrium carrier concentrations Diffusion Process Current Density Mechanisms Diffusion Electric Field Einstein Relation Continuity Equation Diffusion Length Haynes-Shockley Experiment Generalized Ohm’s Law (Quasi-Fermi Levels) Photo conductive devices 28 October 2002

30 Next Time - Semi-conductor Junctions
Fabrication of p-n junctions p-n Junction equilibrium conditions contact potential Fermi Level Space Charge Forward and Reverse Biased Junctions Steady State Conditions Reverse Bias Breakdown A-C conditions Diode Operation Capacitance of the p-n junction Varactor Diode Shottky Barriers 28 October 2002

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