- Intact As-Grown Crystal Morphology: Preserves natural octahedral and hexahedral crystals for maximum strength and durability.
- High Crystal Strength and Wear Resistance: Ensures reliable performance under high-load and long-cycle processing conditions.
- Excellent Thermal Stability: Maintains cutting performance in high-temperature grinding and polishing environments.
- High Purity at PPM Level: Minimizes contamination and supports clean, precision processing.
- Concentrated Particle Size Distribution: Provides stable, predictable cutting behaviour and consistent surface quality.
- Long Service Life and Energy Efficiency: Reduces tool wear and overall processing cost.
AGD – As-grown Micron Diamond Powder
20+ Years Experience
Ultra-Precision Quality
Customized Solutions
AGD is an as-grown monocrystalline micron diamond powder designed for high-performance grinding, cutting, and polishing applications where crystal integrity, durability, and surface quality are critical. Classified directly from raw HPHT synthetic diamond without crushing or reshaping, AGD preserves its natural octahedral and hexahedral crystal morphology, delivering excellent wear resistance, thermal stability, and long service life in demanding industrial processes.
Features
Specifications
| Item | Details |
|---|---|
| Available Sizes (µm) | 15–25, 20–30, 22–36, 20–40, 30–40, 30–50, 36–54, 40–60 |
| Surface Treatment | Titanium coating available Nickel coating available |
Applications
Semiconductor
Used in high-precision grinding and cutting of semiconductor materials.
- Wafer grinding and edge grinding
- Sapphire, SiC, GaN, and silicon wafer cutting
- Precision polishing processes
Optical & Optoelectronic
Suitable for precision machining of hard and brittle optical materials.
- Optical component grinding
- Precision surface finishing
- High-quality contour processing
Aerospace
Applied in machining advanced materials requiring stability and durability.
- Precision grinding of aerospace components
- Hard and brittle material finishing
- High-reliability surface processing