Multi-Layer Titanium Carbide MAX Phase Micron Powder (Ti₂CTx, 2–20 µm, Purity: 98+%) is a high-performance material from the MAX phase family, offering a unique combination of metallic and ceramic properties. With a particle size range of 2–20 micrometers and 98+% purity, this powder demonstrates exceptional mechanical strength, thermal stability, oxidation resistance, and electrical conductivity. It is ideal for use in high-performance applications in aerospace, energy systems, electronics, and advanced manufacturing.
1. Key Properties
High Purity (98+%) Ensures minimal impurities, providing consistent and reliable performance for critical applications.
Multi-Layer Structure The multi-layered nature of Ti₂CTx provides enhanced mechanical strength, flexibility, and conductivity, making it ideal for a wide range of industrial and electronic applications.
Thermal Stability Retains its mechanical properties and stability at elevated temperatures, making it suitable for high-temperature environments.
Electrical Conductivity Offers good electrical conductivity, making it perfect for energy storage, conductive coatings, and electronic components.
Oxidation Resistance Exhibits strong resistance to oxidation, ensuring long-term durability in harsh environments.
Particle Size (2–20 µm) The particle size range allows for excellent dispersion and integration in composites, coatings, and other advanced manufacturing processes.
2. Applications
Energy Storage Used in the development of high-performance supercapacitors, batteries, and energy storage devices for efficient energy storage and fast charge/discharge capabilities.
Aerospace Engineering Applied in high-performance components such as turbine blades, exhaust systems, and thermal protection materials, where thermal stability and mechanical strength are critical.
Electronics Incorporated into electrical contacts, capacitors, sensors, and flexible electronics that require both conductivity and heat resistance.
Catalysis Used in catalytic applications due to its high surface area and conductivity, which enhance the efficiency of chemical reactions.
Cutting Tools and Wear Parts Applied in manufacturing durable cutting tools and wear-resistant components that endure high mechanical stress.
Additive Manufacturing Suitable for 3D printing of custom-engineered, high-performance parts that require superior mechanical properties and durability.
3. Advantages
Superior Mechanical Strength Offers high strength and toughness, ensuring reliability in applications under mechanical stress and wear.
Thermal and Chemical Stability Performs reliably under high temperatures and in chemically aggressive environments, making it ideal for harsh conditions.
Electrical Conductivity Its conductivity makes it suitable for applications requiring both electrical performance and mechanical strength, such as in electronics and energy storage.
Fine Particle Size The fine particle size ensures better integration and uniformity in coatings, composites, and powder-based manufacturing processes.
High Purity Ensures minimal contamination, making it ideal for sensitive applications that demand high-performance and consistent material properties.
4. Recent Trends and Research
Energy Storage Solutions Research into Ti₂CTx’s application in high-performance energy storage devices, such as supercapacitors and high-efficiency batteries, continues to grow.
Aerospace and Defense Investigations focus on enhancing Ti₂CTx’s use in aerospace systems, where components are exposed to extreme temperatures and mechanical stresses.
Electronic Devices Research into Ti₂CTx for use in advanced electronic applications, such as capacitors, sensors, and thermal management devices.
Catalysis and Chemical Processes Studies are exploring Ti₂CTx’s catalytic potential in industrial chemical reactions for improved efficiency.
Additive Manufacturing The role of Ti₂CTx in 3D printing is expanding, offering the ability to create high-performance parts with complex geometries and exceptional properties.
5. Future Prospects
Energy Storage and Conversion Ti₂CTx will continue to be crucial in the development of next-generation energy storage solutions, including supercapacitors and batteries, with improved efficiency and performance.
Aerospace Applications As industries aim for more efficient and high-performance materials, Ti₂CTx will be increasingly used in aerospace for thermal protection, components, and coatings.
Electronics and Flexible Devices The demand for high-performance electronics and flexible devices will drive Ti₂CTx’s use in next-generation sensors, capacitors, and electronic components.
Sustainable Manufacturing With the focus on sustainable production, Ti₂CTx will play an increasing role in eco-friendly manufacturing processes, particularly in energy-efficient technologies.
Advanced Manufacturing As demand for precision-engineered parts grows, Ti₂CTx’s application in additive manufacturing and powder metallurgy will expand, enabling the production of custom parts with tailored properties.
With its 2–20 µm particle size range, 98+% purity, and outstanding mechanical, thermal, and electrical properties, Multi-Layer Titanium Carbide MAX Phase Micron Powder (Ti₂CTx) is an essential material for advanced applications across a wide range of industries. Its ability to provide excellent conductivity, strength, and thermal stability ensures its continued importance in modern materials science and technology.
