Nano yttria (nanoscale Y₂O₃) is a high-performance nanomaterial, presenting as white ultra-fine powder with uniform particle size (nanometer level). It has unique physical and chemical properties different from ordinary yttria, with high specific surface area, good dispersibility and strong surface activity. As a professional nanomaterial supplier, we provide high-purity nano yttria that meets high-end industrial and scientific research requirements. It is widely used in high-tech fields such as advanced ceramics, electronic devices, and new energy materials, serving as a core raw material for high-precision product manufacturing and cutting-edge technological research. The product is produced through advanced nanomaterial preparation technology, with strict quality control throughout the process to ensure stable performance and reliable quality.
FAQ
1. What are its core advantages over regular yttria?
Higher sintering activity, which significantly lowers the sintering temperature of ceramics
Excellent dispersion in composite materials, improving product uniformity
Enhanced chemical stability and thermal shock resistance
Ideal for applications requiring ultra-fine, uniform microstructures
2. What are the main application fields of Nano Yttria?
Advanced Ceramics: As a stabilizer for zirconia ceramics (e.g., dental ceramics, structural ceramics)
Thermal Barrier Coatings: Used in high-temperature-resistant coatings for aerospace and gas turbines
Catalysis: Serves as a support or additive in petrochemical and environmental catalysts
Optical Materials: Used in transparent ceramics and high-performance polishing slurries
Product Uses
1. Advanced Ceramic Field
As a key additive for advanced ceramics, nano yttria can improve the density, hardness and high-temperature resistance of ceramic products, and is widely used in the production of high-performance ceramic parts, electronic ceramic substrates and special ceramic materials.
2. Electronic & New Energy Field
Used as a dopant and functional material in electronic components, it can improve the electrical performance and stability of electronic devices (such as capacitors, semiconductors). It is also an important raw material for new energy materials (such as lithium battery additives), helping to improve the performance of new energy products.
3. Coating & Polishing Field
It is used as a raw material for high-end coatings (such as thermal barrier coatings, anti-corrosion coatings), which can enhance the wear resistance, high temperature resistance and corrosion resistance of the coating. It is also used as a high-precision polishing agent in optical, electronic and other fields to achieve ultra-fine polishing effects.
4. Scientific Research & High-Tech Materials
As a core raw material for scientific research, it is widely used in the research and development of new materials (such as superconducting materials, composite materials), and provides support for the research of cutting-edge technologies in material science, chemistry and other fields.
5. Other High-End Applications
It is used as a functional additive in the fields of optical materials, biomedical materials (auxiliary materials), and can also be applied to the preparation of high-performance catalysts to improve catalytic efficiency and stability.
