Kronos Fusion Energy Incorporated is at the forefront of developing advanced aneutronic fusion technology, aiming to achieve a fusion energy gain factor (Q) of 40. Our mission is to provide clean, limitless energy solutions for industrial, urban, and remote applications.
DIAGNOSTIC MATERIAL
Beryllium Carbide (Be2C) (DM-Be2C-008): Used in diagnostic systems for its high neutron reflection and low activation properties, beryllium carbide enhances neutron flux measurements, contributing to more accurate and reliable diagnostics.
Single-crystalline Materials (Rhodium and Molybdenum) (DM-SC-009): These materials provide high precision and stability for diagnostic components, essential for accurate measurements and control in fusion reactors.
Fused Silica (DM-FS-010): Known for its high optical transparency and radiation resistance, fused silica is used in diagnostic windows and optical systems, ensuring clear and accurate measurements.
Synthetic Crystalline Quartz (DM-SCQ-011): This material offers high stability and transparency for diagnostics, enabling precise measurements in high-radiation environments, which is vital for monitoring and controlling the fusion process.
Barium Fluoride (DM-BF-012): With high optical transmission in the UV range, barium fluoride is used in diagnostic applications requiring high transparency and radiation resistance, supporting effective monitoring of the reactor's conditions.
316L Stainless Steel (DM-SS-013): Provides good corrosion resistance and mechanical properties, widely used in diagnostic instruments and structural applications within the reactor environment.
Zerodur (DM-Z-014): A glass-ceramic with near-zero thermal expansion, offering high stability for precision instruments in varying thermal environments, ensuring consistent performance in diagnostic systems.