Expert-level semiconductor materials covering band theory, silicon processing, compound semiconductors, wide bandgap materials, and semiconductor device fundamentals.
Valence band: filled electron states, top defined by valence band maximum. Conduction band: empty states electrons occupy when excited. Bandgap: energy gap between valence and conduction band maxima. Direct bandgap: GaAs, momentum conserved in optical transitions, good for LEDs. Indirect bandgap: silicon, phonon required for optical transition, poor emitter.
Crystal growth: Czochralski and float zone for single crystal ingots. Doping: phosphorus or arsenic for n-type, boron for p-type. Carrier concentration: n times p = ni squared at equilibrium. Mobility: electron mobility higher than hole mobility in silicon. Oxidation: thermal oxide SiO2 forms on silicon surface, excellent gate dielectric.
GaAs: high electron mobility, direct bandgap, microwave and photonic devices. InP: higher electron velocity than GaAs, telecom laser wavelengths. III-V epitaxy: MBE and MOCVD for heterostructure growth. Heterostructures: quantum wells from bandgap engineering.
SiC: 3.26 eV bandgap, high breakdown field, power electronics to 200 C. GaN: 3.4 eV bandgap, 2DEG at AlGaN/GaN interface, high power and frequency. Ga2O3: 4.8 eV ultrawide bandgap, high breakdown voltage, emerging power device. Diamond: 5.5 eV, ultimate power semiconductor material, processing challenges.
| Pitfall | Fix |
|---|---|
| Ignoring surface states in compound semiconductors | Surface passivation critical for device performance |
| Lattice mismatch in heterostructures | Calculate critical thickness before growing strained layer |
| Thermal resistance limiting GaN device | Design thermal management from start |
| Assuming silicon processes transfer to compound semiconductors | Each material has unique process requirements |