๐ก LEDs
โน๏ธ
Why we care LEDs are PN junction diodes that emit light through electroluminescence. But unlike regular diodes, theyโre engineered to convert electrical energy into visible photons efficiently.
This note scaffolds the physics, material choices, and design optimizations that make LEDs possibleโand powerful.
๐ฌ Core Principle: Electroluminescence
- In forward bias, electrons from the N-type region recombine with holes in the P-type region.
- In direct band gap materials, this recombination releases energy as photons (light).
- In indirect band gap materials (like silicon), energy is lost as heat instead.
๐ง LEDs use direct band gap semiconductors to favor radiative recombination.
๐งช Material Engineering
| Material | Band Gap (eV) | Color Emitted | Notes |
|---|---|---|---|
| GaAs | ~1.4 | Infrared | Early LEDs, low visibility |
| AlGaAs | ~1.9 | Red | Common in indicator LEDs |
| InGaN | ~2.3โ2.7 | GreenโBlue | Used in modern high-brightness LEDs |
| GaN | ~3.4 | BlueโUV | Basis for white LEDs via phosphor |
Direct band gap materials allow photon emission without phonon assistance.
๐งฑ Fabrication Techniques
๐น Epitaxial Growth
- Thin layers of semiconductor are grown on substrates like sapphire or SiC.
- Ensures crystal alignment and minimal defects.
๐น Doping and Junction Formation
- Controlled doping creates the P-type and N-type regions.
- Junction is tuned to maximize recombination in the active layer.
๐ Optical Optimization
| Technique | Purpose |
|---|---|
| Dome-shaped lenses | Extract trapped photons |
| Reflective layers | Bounce light outward |
| Surface texturing | Reduce internal reflection |
| Phosphor coating | Convert blue/UV to white light |
These physical alterations amplify visible light and minimize loss.
๐จ Color Tuning and Perception
- Band gap energy determines photon wavelength (color).
- Phosphor coatings re-emit absorbed photons at broader wavelengths โ perceived as white.
- RGB mixing also used in display tech for full-spectrum control.
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