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Semicircular mechanical grade single crystal CVD diamonds

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July 15, 2025
Category Connection: CVD Lab Grown Diamonds
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Tags:
#Single Crystal Diamond Wafer #CVD Diamond Substrates #CVD Lab Created Diamonds
Brief: Discover the exceptional properties of CVD Lab Grown Diamonds, featuring unmatched hardness, chemical stability, and low thermal expansion. Ideal for advanced laser systems, IR imaging, and spectroscopic analysis, these diamonds offer superior performance in demanding applications.
Related Product Features:
  • CVD-grown single crystal diamond provides the broadest light transmission range from 225 nm to 25 μm.
  • Exceptional thermal conductivity exceeding 2000 W/mK for high-power applications.
  • High refractive index (~2.4) ensures efficient transmission across 1-30 μm wavelengths.
  • Surface roughness <10nm minimizes light scattering for superior optical performance.
  • Available in precise sizes like 2mm×2mm×6mm with tight tolerances (±0.05mm).
  • Superior Raman gain (15) and figure of merit (1440) compared to other crystals.
  • Chemically inert and radiation-resistant, suitable for hazardous environments.
  • Optimized for mid-infrared radiation measurement with triangular prism design.
Faqs:
  • What makes CVD Lab Grown Diamonds superior to other high gain Raman crystals?
    CVD diamonds offer a higher Raman gain (15) and figure of merit (1440), along with exceptional thermal conductivity (>2000 W/mK) and chemical stability, making them ideal for high-power and precision applications.
  • What are the key applications of these CVD diamonds?
    These diamonds are used in high-power CO₂ lasers, IR imaging, spectroscopic analysis, RF technology, and compact optics due to their broad transmission range and durability.
  • What are the dimensional tolerances for these diamonds?
    The diamonds come with transverse tolerances of ±0.05mm and thickness tolerances of ±0.1mm, ensuring precise fit and performance in optical systems.
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