Technical Specifications:
- Chemical Composition:
- Primary Ingredient: Zirconium Diboride (ZrB₂).
- Purity: 99% (high purity for industrial and technological applications).
- Particle Size:
- Particle Size: 750 nm (nanometers).
- Particle Shape: Irregular or hexagonal, depending on the synthesis method.
- Crystal Structure:
- Structure: Hexagonal, contributing to exceptional hardness and thermal conductivity.
- Thermal Properties:
- Melting Point: ~3,240°C, making it suitable for extreme thermal environments.
- Thermal Conductivity: High (~60–120 W/m·K), enabling efficient heat dissipation.
- Thermal Stability: Excellent performance at elevated temperatures.
- Mechanical Properties:
- Hardness: Very high (~9–10 on the Mohs scale).
- Density: ~6.1 g/cm³.
- Color: Grayish-black.
Applications:
- Refractory Materials:
- Purpose: High thermal resistance and melting point make ZrB₂ ideal for high-temperature applications.
- Application: Used in furnace linings, crucibles, and other high-temperature industrial components.
- Aerospace and Defense:
- Purpose: Combines lightweight properties with high strength and thermal stability for aerospace applications.
- Application: Utilized in hypersonic flight systems, rocket nozzles, and thermal protection systems.
- Cutting Tools and Wear-Resistant Components:
- Purpose: High hardness and wear resistance make ZrB₂ suitable for machining applications.
- Application: Used in carbide tools, cutting blades, and wear-resistant inserts.
- Coatings:
- Purpose: Provides oxidation resistance and wear protection.
- Application: Applied as a coating for high-stress and high-temperature machinery and equipment.
- Electronics:
- Purpose: High electrical conductivity and thermal stability make ZrB₂ suitable for electronic components.
- Application: Used in electrical contacts, electrodes, and thermal management systems.
- Nuclear Applications:
- Purpose: Excellent thermal and chemical stability make it suitable for nuclear environments.
- Application: Used in nuclear reactors and as a structural material in advanced nuclear systems.
- Energy Applications:
- Purpose: Enhances the performance and stability of energy storage systems.
- Application: Used in batteries, supercapacitors, and other energy systems for improved efficiency.
- Additive Manufacturing:
- Purpose: Enhances the thermal and mechanical properties of 3D-printed materials.
- Application: Incorporated into powders for additive manufacturing of high-performance components.
- Abrasives:
- Purpose: High hardness makes ZrB₂ ideal for abrasive applications.
- Application: Used in grinding wheels, polishing compounds, and other abrasive tools.
- Composites:
- Purpose: Reinforces composites to improve mechanical strength and thermal resistance.
- Application: Integrated into metal and ceramic matrix composites for advanced industrial applications.
Key Benefits:
- High Melting Point: Suitable for extreme temperature applications such as aerospace and refractory systems.
- Superior Hardness and Wear Resistance: Ideal for cutting tools, abrasives, and protective coatings.
- Thermal and Electrical Conductivity: Efficient heat dissipation and electrical performance.
- Oxidation Resistance: Maintains integrity under oxidative conditions.
- Versatility: Applicable across industries such as aerospace, defense, energy, and manufacturing.
Zirconium Diboride Nanopowder (ZrB₂) is a high-performance material for refractory applications, aerospace, cutting tools, coatings, and electronics, offering exceptional thermal stability, hardness, and oxidation resistance for advanced technological and industrial innovations.
