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6.772/SMA5111 - Compound Semiconductors Lecture 3 - Simple Heterostructures - Outline Energy band review Energy levels in semiconductors: Zero reference,

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Presentation on theme: "6.772/SMA5111 - Compound Semiconductors Lecture 3 - Simple Heterostructures - Outline Energy band review Energy levels in semiconductors: Zero reference,"— Presentation transcript:

1 6.772/SMA5111 - Compound Semiconductors Lecture 3 - Simple Heterostructures - Outline Energy band review Energy levels in semiconductors: Zero reference, χ, E g, E c, E v Homojunctions using bands - a review Heterojunction band profiles (the Depletion Approximation extended) Abrupt junctions: 1.Issues new to heterojunctions: Δ χ, Δ E g, Δ E c, Δ E v 2. Alignment options/types 3. Type I heterojunctions: a. N-p: i. In equilibrium; ii. With applied bias b. P-n c. Iso-type: P-p, N-n Modulation doping: 1. Motivation, concept 2. Carrier concentrations Graded compositions: 1. In bulk regions 2. At heterojunctions (impact on spikes)

2 Energy band edge picture - review Band edge energies The band edge energies relative to the vacuum reference level and to each other are a property of the semiconductor Electron affinity, χ: Conduction band edge to vacuum ref. Energy gap, E g : Valence band edge to conduction band edge Fermi level Depends additionally on the doping level n o = N c exp[-q(E c -E f )/kT] and thus E c - E f = (kT/q) ln (N c /n o ) and/or p o = N v exp[-q(E f -E c )/kT] and thus E f -E c = (kT/q) ln (N v /p o ) Work function, Φ: Fermi level to vacuum ref.

3 Homojunctions - band picture, depletion approximation Band picture a. Isolated n- and p-type: i. Have same vacuum ref., ii. Fermi levels differ iii. Both materials neutral

4 Homojunctions - band picture, depletion approximation Band picture, cont. b. Electrically connected: i.Charge shifts between sides ii. Fermi levels shift until equal iii. Vacuum ref. is now -q Φ (x) where Φ (x) = (q/e)∫∫ρr(x) dx dx iv. Depletion approximation is a good estimate of ρ(x)

5 Homojunctions - band picture, depletion approximation Band picture a. Isolated N- and p-type: (taking an N-p junction as the example) Similar to homojunction except that now the two materials have different electron affinities, energy gaps, dielectric constants, and effective masses.

6 Homojunctions - band picture, depletion approximation Band picture, cont. b. Electrically connected: i. Charge shifts between sides ii. Fermi levels shift until equal iii. Vacuum ref. is now -q Φ (x) where Φ (x) = (q/e)∫∫ρ(x) dx dx iv. E c (x) is -q Φ (x) -χ(x) and E v (x) = -q Φ (x) - [χ(x) +E g (x)]

7 Homojunctions - band picture, depletion approximation Band picture, cont. c. Useful Observations: i. The final electrostatic potential profile, Φ (x), is primarily a consequence of the doping levels. ii. The band-edge profiles, E c (x) and E v (x), are additionally a consequence of the electron affinity and energy gap profiles, χ(x) and E g (x), respectively. iii. In an abrupt heterojunction there are frequently discontinuities in the conduction and valence band edges at the junction.

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