Technical Specifications:
- Chemical Composition:
- Primary Ingredient: Zirconium Carbide (ZrC).
- Purity: 99+% (high purity for advanced industrial applications).
- Particle Size:
- Particle Size: 20 nm (nanometers).
- Particle Shape: Typically spherical or slightly irregular, depending on synthesis.
- Crystal Structure:
- Structure: Cubic, providing excellent mechanical, thermal, and electrical properties.
- Thermal Properties:
- Melting Point: ~3,550°C, making it suitable for extreme temperature environments.
- Thermal Conductivity: ~20–30 W/m·K, ensuring effective heat dissipation.
- Thermal Stability: Maintains stability under high-temperature conditions.
- Mechanical Properties:
- Hardness: Extremely hard (~9 on the Mohs scale), suitable for wear-resistant applications.
- Density: ~6.73 g/cm³.
- Color: Dark gray to black.
Applications:
- Refractory Materials:
- Purpose: High thermal stability and melting point make ZrC ideal for high-temperature environments.
- Application: Used in furnace linings, crucibles, and other refractory components.
- Aerospace and Defense:
- Purpose: Combines lightweight properties with high strength and heat resistance for aerospace components.
- Application: Utilized in hypersonic vehicles, rocket nozzles, and heat shields.
- Cutting Tools and Wear-Resistant Components:
- Purpose: Exceptional hardness and wear resistance make ZrC suitable for cutting and machining applications.
- Application: Used in carbide tools, drills, and high-performance cutting edges.
- Coatings:
- Purpose: Provides enhanced oxidation resistance, wear resistance, and thermal stability.
- Application: Applied as a protective coating for tools, engine components, and high-stress industrial parts.
- Electronics:
- Purpose: High electrical conductivity and thermal stability make ZrC ideal for electronic applications.
- Application: Used in conductive coatings, resistors, and thermal management systems.
- Energy Storage:
- Purpose: Improves the stability and efficiency of energy storage devices.
- Application: Incorporated into electrodes for batteries, supercapacitors, and advanced energy systems.
- Catalysis:
- Purpose: Acts as a support or active material in catalytic reactions.
- Application: Used in hydrogen production, hydrocarbon processing, and environmental remediation.
- Additive Manufacturing:
- Purpose: Enhances the mechanical and thermal properties of 3D-printed materials.
- Application: Integrated into powders for high-performance additive manufacturing.
- Nuclear Applications:
- Purpose: High melting point and resistance to radiation make ZrC suitable for nuclear systems.
- Application: Used in advanced nuclear reactors as a structural material.
- Composites:
- Purpose: Reinforces composites to improve thermal conductivity, mechanical strength, and wear resistance.
- Application: Incorporated into metal and ceramic matrix composites for aerospace and industrial applications.
Key Benefits:
- Ultra-High Melting Point: Suitable for extreme temperature applications like aerospace and refractory systems.
- Exceptional Hardness: Provides superior wear resistance for cutting tools and coatings.
- Thermal and Electrical Conductivity: Ensures efficient heat dissipation and electrical performance.
- Chemical Stability: Resistant to oxidation, corrosion, and chemical degradation.
- Nanoscale Advantages: High surface area enhances reactivity and integration into composites and coatings.
Zirconium Carbide Nanopowder (ZrC) is a cutting-edge material for refractory applications, aerospace components, cutting tools, coatings, and energy systems, offering unparalleled thermal resistance, hardness, and durability for advanced technological and industrial innovations.