TECHNICAL SPECIFICATIONS

High-Performance
Material Solutions

HIGH-TECH MATERIAL

PolyCrystal CVD Diamond Wafer

Product Description

Polycrystalline CVD diamond (PCD) plates provide excellent thermal management with high thermal conductivity, though slightly lower than single-crystal diamonds. They are ideal for use in heat sinks and spreaders in electronics, RF devices, and power systems.

Specifications & Tolerances

  • Diameter: 10 mm to 100 mm
  • Thickness: 300um & 500um
  • Thermal conductivity: Up To 1800 W/mK
  • Surface: As grown & polished
  • Thickness Tolerance: +/- 5%
  • Transmittance: up to 65%

Key Advantages

Thermal Conductivity

Superior heat dissipation, ideal for high-power electronics.

Low Expansion

Reduces stress between materials during temperature changes.

Chemical Stability

Resistant to oxidation and chemical reactions.

Wear Resistance

Ensures durability and long-lasting performance.

Radiation Resistance

Suitable for space and high-radiation environments.

Electrical Insulation

Useful in applications requiring thermal management.

PolyCrystal CVD Diamond Wafer
Single Crystal CVD Diamond Plate
CORE PRODUCT

Single Crystal CVD Diamond Plate

Product Description

Single-crystal CVD diamond plates offer superior thermal conductivity (up to 2200 W/m·K), making them ideal for heat dissipation in high-power electronics, lasers, RF devices, and semiconductors.

Standard Size: 2mm to 20mm

Specifications & Tolerances

  • Edges: Laser Cut
  • Face Orientation: 100
  • Laser Kerf: 3°
  • Lateral Tolerance: +0.2/-0 mm
  • Side 1/2 Roughness: < 2 - 30 nm
  • Thickness Tolerance: +/- 0.05 mm
  • Thickness Dim: 0.3-0.5mm

Material Properties

Nitrogen concentration: < 5 ppb (Optional) N2 Controlled based on Requirements

Operational Advantages

Thermal Conductivity

Higher than polycrystalline, offering superior heat dissipation.

Isotropic Properties

Uniform thermal performance in all directions.

Thermal Stability

Performs well at extreme temperatures.

Electrical Insulation

Non-conductive, useful in electronic devices.

Minimal Defects

Ensures higher reliability and efficiency.

Durability

Resistant to wear and chemical exposure.

QUANTUM GRADE

Ultra-High Purity Epi Layer on SCD

Product Classification

Ultra-High Purity 30 to 50 μm Epitaxial Layer on Single Crystal Diamond.

Dimension:
5mm to 20mm

Specifications & Tolerances

  • Boron concentration: < 5 ppb
  • Surface roughness: < 2 nm
  • Nitrogen concentration: < 5 ppb
  • Orientation: Typically (100)

Target Applications

  • High-frequency & high-power devices
  • Optical windows with ultra-low absorption
  • Quantum optics: NV centre stability
  • Ultrafast photodetectors

Key Industries

  • Quantum Photonics
  • Laser & LIDAR Systems
  • High-Frequency RF/Power Electronics
  • Advanced Sensor Technologies
Ultra-High Purity Epi Layer on SCD
Boron Doped SCD Diamond
CONDUCTIVE DIAMOND

Boron Doped SCD Diamond

Specifications & Tolerances

Size: 2mm to 20mm
  • Thickness: 0.3 mm – 1 mm
  • Boron concentration: 1017–1021 atoms/cm3
  • Orientation: (100)
  • Electrical conductivity: Variable
  • Resistivity: ~1 mΩ·cm
  • Surface roughness: Polished ≤ 2nm

Applications

  • Electrochemical sensors and electrodes
  • Radiation-hardened electronics
  • p-type semiconductor devices

Industries

  • Harsh-Environment Electronics
  • Diamond-based Transistors
  • Electrochemical Sensing
THERMAL MANAGEMENT

Cu-Diamond Composite Material

Specifications & Tolerances

  • Thermal conductivity: 500–700 W/m·K
  • CTE tailored to match Si or GaN
  • Thickness: 0.5 mm – 5 mm
  • Surface: Lapped, Laser Cut

Applications

  • High-power RF amplifier baseplates
  • Space-grade thermal interface materials
  • IGBT module heat sinks
  • LED packaging

Industries

  • Power Electronics
  • Satellite and Defense Avionics
  • Automotive EV Modules
  • LED Packaging
Cu-Diamond Composite Material
Aluminium-Diamond Composite Plates
ADVANCED COMPOSITE

Aluminium-Diamond Composite Plates

Specifications & Tolerances

  • Diamond volume: 30–50%
  • Thermal conductivity: 350–500 W/m·K
  • CTE matched with Si or GaAs
  • Surface: Lapped, Laser Cut
  • Thickness: 0.3 mm – 10 mm

Applications

  • Heat spreaders in telecom and radar
  • Optoelectronic devices thermal management
  • Laser diode mounting
  • LED arrays

Industries

  • Telecom Infrastructure
  • Medical Lasers
  • Consumer Electronics
  • Aerospace Electronics
HYBRID WAFER

GaN Bonded on PCD Wafer (4-inch)

Specifications & Tolerances

  • PCD wafer: 2-4 inch, 300–500 μm thick
  • GaN layer: Transferred or bonded
  • Bonding method: Plasma-assisted
  • Interface resistance: Minimized

Applications

  • GaN-on-Diamond HEMTs
  • GaN LEDs with enhanced heat dissipation
  • Pulsed RF Power Amplifiers
  • MMICs

Industries

  • RF & Microwave
  • High-Speed Switching Systems
  • Space-grade Electronics
  • Defence Electronics
GaN Bonded on PCD Wafer (4-inch)
GaN on Diamond
NEXT-GEN SEMICONDUCTOR

GaN on Diamond

Specifications & Tolerances

  • GaN thickness: 0.5 μm – 5 μm
  • Substrate: SCD (100) or (111)
  • Interface: Buffer layer (AlN/AlGaN)
  • Quality: Low dislocation density
  • Thermal resistance: Ultra-low (< 0.1 K/W)

Applications

  • GaN HEMTs with high power density
  • Next-gen radar & comm systems
  • RF and 5G devices
  • Thermal management-critical devices

Industries

  • Wireless Communications
  • 5G Infrastructure
  • Military Radar
  • High-Power Electronics