Dititanium Trioxide

Product Overview

Dititanium trioxide, systematically known as Titanium(III) oxide, represents a critical inorganic compound within the realm of advanced material science. Characterized by its distinctive violet hexagonal crystal structure, this substance serves as a foundational component for various high-performance industrial applications. Our manufacturing process ensures exceptional consistency and chemical stability, making it an ideal choice for researchers and industrial engineers requiring reliable raw materials for specialized synthesis.

With a molecular formula of O3Ti2 and a molecular weight of approximately 143.73 g/mol, this compound exhibits robust thermal properties, including a melting point exceeding 2130 degrees Celsius. Such characteristics underscore its suitability for environments subjected to extreme thermal stress. Furthermore, the material maintains stability under normal temperatures and pressures, facilitating safer handling and storage protocols within standard laboratory and factory settings.

Technical Specifications and Quality Control

Quality assurance is paramount in the production of fine chemicals. Our Dititanium trioxide undergoes rigorous analytical testing to guarantee ultra-high purity levels suitable for sensitive electronic and ceramic formulations. The following table outlines the key performance indicators and test results associated with our current production batch:

The stringent control of metallic impurities, such as iron, lead, and copper, is essential for preventing unwanted catalytic effects or discoloration in downstream products. Our factory standard ensures that every shipment conforms to these tight tolerances, supported by a comprehensive Certificate of Analysis (COA).

Industrial Applications

Due to its unique electronic structure and physical properties, Titanium(III) oxide is utilized across several specialized sectors. In the ceramics industry, it acts as a pigment and structural modifier, enhancing the durability and aesthetic qualities of glazes and bodies. In the field of electronics, it serves as a conductive additive or precursor for developing specialized coatings that require specific electrical resistance profiles.

• Advanced ceramic manufacturing and glaze formulation.
• Conductive coatings and electronic material synthesis.
• Research and development in inorganic chemistry.
• Production of specialized titanate compounds.

Storage and Handling

To maintain the integrity of the material, proper storage conditions must be observed. The product should be kept in tightly closed containers to prevent contamination from moisture or atmospheric particulates. Storage areas should be cool and dry, away from incompatible substances. While stable at normal conditions, standard industrial safety practices regarding dust inhalation and skin contact should be followed during handling procedures.