Fluorphlogopite (also known as artificial mica, synthetic mica large crystals) is a silicate artificial mica crystal. It is a mica crystal melted in a platinum crucible at a high temperature of 1500℃ under strict process conditions and material ratios. As well as being resistant to acids, alkalis, transparent, separable and flexible, it is an important non-metallic insulating material for modern industries and high-tech industries such as motors, electrical appliances, electronics, and aviation. The Fluorophlogopite mica is parallel extinction, positive extension, secondary diaphragm interference color, secondary crystal negative light, optical axis angle of about 10 °. Because the Fluorophlogopite mica contains less impurities, from ultraviolet to infrared, its light transmittance is relatively high. For ultraviolet light, natural mica is basically impermeable, and Fluorophlogopite mica can penetrate to nearly 0.2 μm. The natural mica has a distinct absorption peak at 2.75 μm, but the Fluorophlogopite mica does not, which is an important sign of the substitution of Fˉ for (OH)ˉ. It can be seen that Fluorophlogopite mica is also a good light transmitting material from ultraviolet (0.2 μm) to infrared (5 μm).

Optical Field Fluorophlogopite, a type of mica mineral, is gaining attention for its potential applications in the field of optics. Its unique combination of properties, including high transparency, low birefringence, and excellent thermal stability, makes it an intriguing candidate for optical components and systems. Fluorophlogopite's ability to withstand high temperatures and harsh environmental conditions while maintaining optical clarity and stability positions it as a promising material for use in lenses, prisms, and other optical devices.

Vacuum insulation field Fluorophlogopite, a type of mica mineral, has shown promise in the field of vacuum insulation. Due to its excellent thermal and chemical stability, low thermal conductivity, and resistance to high temperatures, fluorophlogopite is being explored as a potential material for vacuum insulation applications. Its ability to maintain structural integrity in extreme conditions makes it an attractive candidate for use in vacuum insulation panels, which are utilized in various industries for efficient thermal insulation. The unique properties of fluorophlogopite offer the potential to enhance the performance and longevity of vacuum insulation systems, contributing to improved energy efficiency and thermal management in diverse applications ranging from refrigeration to aerospace technologies. Ongoing research and development efforts aim to further explore the suitability of fluorophlogopite for vacuum insulation and expand its impact in this critical field.

Features:

1. Excellent electrical insulation and high temperature resistance;

2. Low high-frequency dielectric loss, stable dielectric constant, no aging, not easy to break, easy to debug;

3. Good high temperature resistance, corrosion resistance and light transmittance;

4. Good flatness, no adsorption of impurities;

5. Excellent vacuum sealing performance.

Applications:

1. Fluorocrystalline mica observation window for infrared monitoring system;

2. Advanced insulating gaskets for aerospace equipment such as spacecraft and monitoring satellites;

3. Ideal waveguide sealing windows and dielectric sheets for military radars;

4. Nanomaterial growth substrates;

5. Atomic force microscope substrates;

6. Observation window for high-pressure boiler water level gauges in thermal power plants.

Performance curve of fluorophlogopite mica: