Titanium Diboride Micron Powder (TiB2, 98.5+%, 2.5-13 μm )

Titanium Diboride Micron Powder (TiB2, 98.5+%, 2.5–13 µm) is a high-performance ceramic material known for its exceptional hardness, thermal conductivity, and resistance to chemical attack. With a particle size range of 2.5 to 13 micrometers and a purity of 98.5+%, this powder is designed for demanding industrial and engineering applications requiring strength, wear resistance, and stability under extreme conditions. It is widely used in aerospace, electronics, tool manufacturing, and energy systems.

1. Key Properties

Exceptional Hardness Delivers superior wear and abrasion resistance, making it ideal for high-stress industrial applications.
Thermal Conductivity Ensures efficient heat dissipation, maintaining performance in high-temperature environments.
Chemical Stability Resists oxidation and chemical attack, providing durability in aggressive environments.
Electrical Conductivity Exhibits excellent electrical conductivity, making it suitable for electrode applications.
Particle Size (2.5–13 µm) Optimized for uniform integration into composites and advanced manufacturing processes.
Purity (98.5+%) Ensures reliable performance in demanding industrial applications.

2. Applications

Aerospace Engineering Utilized in lightweight, high-strength components exposed to extreme thermal and mechanical conditions.
Electronics Applied in semiconductor devices and electrical contacts for its excellent conductivity and durability.
Cutting Tools Incorporated in wear-resistant coatings and tool manufacturing for enhanced durability and efficiency.
Energy Systems Used in fuel cells and batteries for its electrical conductivity and chemical stability.
Advanced Ceramics Integral to high-strength ceramics for industrial processes and high-temperature applications.
Defense and Armor Employed in armor plating for its hardness and resistance to impact and abrasion.

3. Advantages

Superior Hardness and Wear Resistance Extends the lifespan of tools and components in abrasive environments.
Thermal Stability Performs reliably under extreme heat, suitable for high-temperature applications.
Chemical Durability Maintains integrity in chemically aggressive and oxidizing environments.
Fine Particle Size Supports uniform application and dispersion in advanced composites and coatings.
High Purity Reduces contamination risk, ensuring reliability in precision applications.

4. Recent Trends and Research

Aerospace Applications Research focuses on optimizing TiB2 for high-performance components in advanced aerospace systems.
Electronics Advancements Studies explore its role in semiconductors, electrodes, and thermal management systems.
Tooling and Coatings Development of TiB2-based coatings for cutting and machining tools to enhance wear resistance and longevity.
Energy Systems Investigations emphasize its use in fuel cells, batteries, and other energy storage technologies.
Additive Manufacturing Progress in 3D printing integrates TiB2 powders for fabricating high-performance, precision-engineered parts.

5. Future Prospects

Aerospace and Defense TiB2 will remain a critical material for developing lightweight, durable components and protective armor.
Energy Systems Development Its application in energy storage and fuel cells will grow as industries prioritize renewable energy.
Advanced Manufacturing TiB2 powders will support innovations in 3D printing and powder metallurgy for high-performance parts.
Cutting-Edge Tools Enhanced use in cutting tools and coatings will meet the demands of modern machining and manufacturing.
Eco-Friendly Production Research into sustainable production methods will align TiB2 with green industry practices.

With its 2.5–13 µm particle size, 98.5+% purity, and exceptional mechanical, thermal, and chemical properties, Titanium Diboride Micron Powder (TiB2) is a versatile material for advanced applications in engineering, electronics, and industrial manufacturing. Its adaptability and high performance ensure its significance in modern materials science and engineering.