Graphite Fluoride Micron Powder,10-20 micron, F/C Ratio : 1.0

Graphite Fluoride Micron Powder (10-20 µm, F/C Ratio: 1.0)

Technical Specifications:

• Material: Graphite Fluoride (C₆F₆)
• Purity: Typically 99.9% or higher
• Particle Size: 10-20 µm (microns)
• Fluorine/Carbon Ratio (F/C): 1.0
• Shape: Typically irregular, may also include spherical particles depending on the manufacturing process
• Density: Approximately 2.1–2.3 g/cm³ (for graphite fluoride)
• Melting Point: Decomposes at around 200-250°C (392-482°F), depending on formulation
• Boiling Point: Sublimes at around 2,600°C (4,712°F)
• Chemical Composition:
  • Carbon (C): ~50%
  • Fluorine (F): ~50%

Applications:

1. Li-ion Battery Anodes:
   • Graphite Fluoride is widely used as an additive in Li-ion battery anodes to improve capacity and voltage stability. The F/C ratio of 1.0 provides a balanced level of fluorine, optimizing the electrochemical properties of the anode material. The 10-20 µm powder is used to create composite anodes that offer enhanced performance in high-capacity batteries for electric vehicles, renewable energy storage, and portable electronics.
   • The micron powder ensures uniform distribution of fluorine and carbon in the anode, leading to improved energy density, longer cycle life, and greater charge/discharge efficiency.
2. High Energy Density Batteries:
   • Graphite Fluoride is used in the development of high-energy-density batteries due to its ability to store more electrical energy compared to conventional graphite-based anodes. The F/C ratio of 1.0 maximizes the electrochemical stability and capacity retention of the battery, making it ideal for next-generation lithium-ion batteries designed for electric vehicles and large-scale energy storage systems.
   • The micron powder enables the fabrication of high-performance battery cells that can deliver greater power and longer operational life.
3. Supercapacitors:
   • Graphite Fluoride is used in the production of supercapacitors, which are energy storage devices capable of rapid charge/discharge cycles. The micron powder contributes to high capacitance and power density, improving the efficiency of supercapacitors used in applications such as energy harvesting, electric vehicle powertrains, and uninterruptible power supplies (UPS).
   • The fluorine content enhances charge storage and increases the stability of the supercapacitor material, ensuring longer cycle life and better performance.
4. Energy Storage Devices:
   • Graphite Fluoride is explored for use in energy storage devices such as batteries and capacitors that require high energy density, fast charge capabilities, and long operational life. The F/C ratio of 1.0 ensures improved energy storage efficiency and reliable performance in both long-duration energy storage and rapid discharge systems.
   • These properties make it an ideal material for renewable energy storage, solar power systems, wind energy storage, and portable electronic devices that require high-capacity energy storage.
5. Power Electronics and Devices:
   • Graphite Fluoride is used in power electronics, particularly for applications requiring high voltage and high current handling. The material’s electrical conductivity and stability under stress make it suitable for components such as high-power transistors, power supplies, and electric motors.
   • The micron powder is used in thin films or coatings for electronic components that require improved conductivity and high thermal stability under high-power conditions.
6. Electrochemical Capacitors:
   • Graphite Fluoride is also used in electrochemical capacitors where it contributes to high-performance energy storage with rapid charge/discharge cycles. The micron powder enhances the surface area and conductivity of the electrodes, making them ideal for energy-efficient capacitors in applications like power backup systems, consumer electronics, and automotive power systems.
   • Graphite fluoride capacitors offer greater energy storage and more efficient power delivery in electric vehicles, automotive systems, and industrial applications.
7. Magnetic Materials and Sensors:
   • Graphite Fluoride can also be used in magnetic materials and sensors. It plays a role in magnetic storage and sensor devices where stable and high-performance materials are required for electromagnetic applications.
   • The micron powder helps enhance magnetic properties, electrical stability, and sensor sensitivity, making it useful for high-frequency devices, magnetic sensors, and data storage systems.
8. Coatings and Lubricants:
   • Graphite Fluoride is used in coatings and lubricants to improve friction reduction and wear resistance. The fluorine content provides low friction properties that are beneficial in industrial machinery, automotive parts, and precision instruments.
   • The micron powder is used in dry lubricants or coatings for mechanical components that operate under high-load or extreme conditions where traditional lubrication would be ineffective or impractical.
9. Research and Development:
   • Graphite Fluoride micron powder is widely used in research and development to explore novel materials and advanced energy systems. Researchers use CdSe powder for battery technology, supercapacitor development, and sensor technologies. The F/C ratio of 1.0 is ideal for studying the material’s electrochemical behavior, surface properties, and energy storage capabilities.
   • The micron powder is also used in the development of advanced composite materials, nanomaterials, and functionalized coatings for emerging technologies in electronic devices, clean energy, and nanoelectronics.

Graphite Fluoride Micron Powder (10-20 µm, F/C Ratio: 1.0) is a high-performance material with outstanding electrochemical properties, high energy storage, and conductivity, making it ideal for Li-ion batteries, supercapacitors, and electrochemical capacitors. Its application across various energy storage systems, power electronics, automotive, electromagnetic components, and lubricants makes it a crucial material in cutting-edge technologies such as electric vehicles, solar power storage, renewable energy systems, and advanced electronics. The fine micron powder enables precise deposition and optimal performance in high-performance energy systems and high-capacity storage devices.