Titanium Dioxide Nanowires Type B (Analytical Grade)

Product Overview
Titanium dioxide nanowires Type B (analytical grade) are synthesized using a hydrothermal method and exhibit a nanowire structure with excellent photocatalytic performance. The unique porous structure allows for efficient light absorption and electron-hole pair generation, significantly enhancing catalytic efficiency. This material is widely used in high-tech applications, including environmental remediation and energy conversion, due to its efficient photocatalytic properties. It undergoes purification, dispersion, and high-temperature calcination to ensure high purity and structural stability.

Key Features

• High Surface Area and Active Surface:The nanowire structure provides a large surface area, enhancing light absorption and reaction activity.
• Outstanding Photocatalytic Performance:The material's efficient generation of electron-hole pairs results in significant photocatalytic effects, particularly beneficial for environmental remediation and energy conversion.
• Strong Chemical Stability:After high-temperature calcination, the material exhibits excellent chemical resistance, making it suitable for various harsh environments.
• Superior Porous Structure:The material features a rich porous structure, ideal for adsorption and separation of various substances.

Applications

• Nanocomposite Fillers:Used as a filler in nanowire polymer composites, metal composites, and ceramic composites.
• Adhesives and Coatings:Enhances adhesives and coatings by improving material performance.
• High-Performance Films:Suitable for the production of high-performance films.
• Nanoporous Ceramic Membranes:Used for chemical and water filtration, especially in strong acid and alkali environments.
• High-Temperature Nonwoven Fabrics:Serves as a raw material for high-temperature nonwoven fabrics.
• White Pigments:Acts as a white pigment for plastics, coatings, rubber, cosmetics, synthetic fibers, paper, and ceramics.
• Surface Coatings:Used as an additive in surface coatings to improve their properties.
• Catalyst Supports:Functions as a support material for catalysts, enhancing catalytic efficiency.
• Photocatalysts:Widely applied in photocatalytic reactions, especially in environmental remediation and energy conversion.
• Dye-Sensitized Solar Cells:Used in dye-sensitized, polymer-based solar cells, and quantum dot solar cells (both photovoltaic and photocatalytic).
• Water Splitting for Hydrogen Production:Applied in hydrogen production processes through water splitting.
• Chemical Sensors:Ideal for high-temperature gas sensors, exhibiting high sensitivity under harsh conditions.
• Lithium Battery Anodes:Serves as an anode material for lithium-ion batteries.
• Fuel Cells:Used as catalyst and support materials in fuel cells.