Silicon carbide (SiC) has emerged as one of the most promising wide-bandgap semiconductors, and among its polytypes, 6H-SiC holds a special place thanks to its balance of properties and established growth technology. Within 6H-SiC substrates, two types exist based on doping: N-type and P-type. This article provides a comparative analysis of the two, from their definitions and properties to their advantages, applications, and development trends.
I. Definition
6H-SiC: A hexagonal polytype of SiC with a crystal structure repeating every six layers and a bandgap of ~3.0 eV.
6H-N-type SiC substrate: Doped with
nitrogen (N), with electrons as majority carriers.
6H-P-type SiC substrate: Doped with
aluminum (Al) or
boron (B), with holes as majority carriers.
II. Properties Comparison
| Feature |
6H-N-type |
6H-P-type |
| Dopant |
Nitrogen (N) |
Aluminum (Al), Boron (B) |
| Conductivity |
N-type (electrons) |
P-type (holes) |
| Resistivity |
Low (0.02–0.5 Ω·cm) |
Higher (0.5–tens of Ω·cm) |
| Bandgap |
~3.0 eV |
~3.0 eV |
| Thermal conductivity |
3–4.9 W/cm·K |
3–4.9 W/cm·K |
| Crystal structure |
Hexagonal |
Hexagonal |
III. Advantages
6H-N-type:Low resistivity, ideal for epitaxial growth.
Mature processing and established supply chain.
Excellent for high-power, high-voltage devices.
6H-P-type:Enables
PN junction formation for diodes.
Useful in optoelectronics and sensor applications.
Provides diversity in device architecture.
IV. Applications
6H-N-type substrates:Power devices: MOSFETs, Schottky diodes, IGBTs.
RF and high-frequency switching devices.
Electronics in harsh environments (high temperature, radiation).
6H-P-type substrates:Research and epitaxy of P-type layers.
Optoelectronic devices: UV detectors, LEDs.
Special power devices using PN junctions or symmetric structures.
V. Development Trends
N-type dominance: The commercial power device industry overwhelmingly uses N-type 6H/4H-SiC substrates.
P-type niche: P-type is mainly used in research and specialized devices due to its higher resistivity and growth challenges.
Scaling up: From 2-inch to 4-inch and 6-inch wafers, with ongoing progress toward 8-inch.
Improved quality: Reducing dislocation density and enhancing epitaxial quality remain central goals.
Complementary role: Future device landscapes may see
6H-SiC substrates (N and P) working alongside
4H-SiC for a diverse range of power and optoelectronic applications.
VI. Summary Table
| Aspect |
6H-N-type |
6H-P-type |
| Role in industry |
Mainstream, widely used |
Specialized, research-focused |
| Strength |
Low resistivity, high-power devices |
PN junction formation, optoelectronics |
| Limitation |
Less suited for P-layer research |
Higher resistivity, lower adoption |
| Market outlook |
Strong and growing |
Niche, but important for innovation |
Conclusion
6H-N-type SiC substrates have become the backbone of the SiC power electronics industry, powering high-voltage MOSFETs, diodes, and IGBTs. In contrast,
6H-P-type substrates remain a niche but valuable material for research, optoelectronics, and PN junction-based devices. Together, they form a complementary ecosystem that will continue to evolve as wafer sizes scale, defect densities fall, and demand for high-performance semiconductors accelerates.
In the long run, the synergy of N-type and
P-type 6H-SiC will help push the boundaries of power electronics, optoelectronics, and beyond.
