Aluminum Oxide Micron Powder ( Al2O3, 99.5+%, 850-1180 µm )

Aluminum Oxide Micron Powder (Al₂O₃, 99.5+%, 850–1180 µm) is a high-purity alumina powder distinguished by its exceptional hardness, chemical resistance, and thermal stability. With a particle size range of 850 to 1180 micrometers, this coarse powder is optimized for applications requiring excellent flowability, consistent packing density, and superior durability. Its 99.5+% purity ensures reliable and consistent performance in advanced ceramics, abrasives, coatings, and high-temperature industrial applications across industries such as aerospace, automotive, and energy.

1. Key Properties

High Purity (≥99.5%) ensures minimal impurities, providing consistent and reliable performance in demanding industrial processes.

Particle Size (850–1180 µm) delivers enhanced flowability and packing characteristics, making it ideal for powder-based manufacturing, abrasive tools, and thermal spraying applications.

Exceptional Hardness ensures superior wear resistance, making it suitable for grinding tools, abrasives, and protective coatings used in high-friction environments.

Thermal Stability enables the powder to maintain structural integrity at temperatures exceeding 2,000 °C, essential for high-temperature and refractory applications.

Chemical Inertness offers durability in chemically aggressive environments, supporting applications in filtration, catalysis, and industrial processing.

2. Applications

Advanced Ceramics & Refractories Alumina is widely used in high-performance ceramics and refractory components, offering exceptional resistance to heat and wear for kiln furniture, nozzles, and industrial parts.

Abrasives & Polishing The 850–1180 µm particle size is ideal for manufacturing grinding wheels, cutting tools, and polishing compounds, ensuring efficient material removal and extended tool performance.

Thermal Barrier Coatings Alumina-based coatings protect turbine blades, engine components, and industrial equipment from oxidation, erosion, and extreme temperatures.

Electronics & Insulation Alumina’s dielectric properties and thermal conductivity make it an essential material for insulating and protecting electronic components, substrates, and housings.

Catalysis & Filtration High-purity alumina serves as a catalyst support and filtration medium, providing stability under high temperatures and corrosive conditions in petrochemical and environmental systems.

3. Advantages

Enhanced Flowability The coarse particle size ensures smooth powder handling and consistent feeding during manufacturing processes like sintering, spraying, and coating.

Wear Resistance Alumina’s hardness ensures durability for tools, components, and coatings exposed to abrasive or high-friction conditions.

Thermal Durability Alumina retains its mechanical properties under extreme heat, making it reliable for refractory linings, thermal barriers, and high-temperature industrial uses.

Chemical Stability Resistance to acids, alkalis, and solvents enhances the longevity of alumina-based products in filtration, catalysis, and chemical processing systems.

Electrical Insulation Alumina’s dielectric properties make it indispensable for insulating components in high-voltage and high-temperature electronic systems.

4. Recent Trends and Research

Additive Manufacturing is adopting coarse alumina powders to create durable and intricate ceramic components using advanced 3D printing techniques.

Advanced Coating Technologies are enhancing alumina-based coatings for improved adhesion, durability, and thermal resistance in aerospace, automotive, and industrial applications.

Optimized Abrasives are being developed to improve cutting efficiency, reduce wear, and enhance precision in industrial and consumer applications.

Sustainability Initiatives are focusing on recycling alumina from used abrasives and ceramic waste, supporting greener manufacturing practices and reducing environmental impact.

Energy Applications are expanding, with alumina increasingly utilized in catalysis, filtration, and energy storage systems to support cleaner and more efficient industrial processes.

5. Future Prospects

High-Performance Ceramics will evolve further with advancements in powder processing and sintering techniques, enabling the production of complex and durable components.

Innovative Coatings leveraging alumina’s thermal and wear-resistant properties will find broader applications in aerospace, automotive, and energy industries.

Medical Applications will expand as alumina’s biocompatibility and wear resistance support the development of surgical instruments, dental tools, and implants.

Lightweight Structural Materials reinforced with alumina will gain prominence in aerospace and automotive sectors, offering enhanced strength-to-weight ratios for high-performance systems.

Clean Energy Solutions will see alumina’s role grow in catalysis, filtration, and energy storage technologies, supporting sustainability goals and innovation in energy systems.

With its 99.5+% purity and 850–1180 µm particle size range, Aluminum Oxide Micron Powder (Al₂O₃, 99.5+%, 850–1180 µm) delivers unmatched durability, thermal stability, and wear resistance for a variety of industrial and high-performance applications. From advanced ceramics and abrasives to protective coatings and electronics, alumina continues to be a cornerstone material in modern engineering and manufacturing.