Sodium titanate nanoribbons

Product Name

^{Name：Sodium titanate nanoribbons}

Product Overview

^{The crystal structure of alkali metal titanates such as sodium titanate (Na2Ti3O7) is composed of Ti-O6 octahedra with common edges and vertices, forming a layered structure. The gaps between layers are occupied by Na+, which can be easily replaced by protons or various metal ions (Li+, Co+, Cd2+, Ru3+, etc.). Therefore, Na2Ti3O7 has a wide range of applications in the adsorption of functional organic compounds and the removal of heavy metals or radioactive ions.}

^{Technical Parameter}

^{Appearance：White powder}

^{Ingredient：Na2Ti3O7}

^{Length:-20μm（SEM:/span>}

^{Width:0-300nm（SEM:/span>}

^{Product Features}

^{Surface activity: The surface has certain active sites and reactive groups, resulting in high surface energy.}

^{Ionic exchange characteristics: It can perform certain ion exchanges, such as the exchange of alkali metal ions.}

^{Convertability: It can be converted into other titanium compound nanostructures through acid treatment and other methods (such as acid treatment of sodium titanate nanotubes and nanoribbons to obtain corresponding titanate nanotubes and nanoribbons).}

^{Application Fields}

^{Drug carrier: Nanoribbons with large specific surface area and special structure can be used to load drug molecules, and their surface properties may be utilized for functional modification to achieve targeted drug transport and controlled release.}

^{Sodium ion battery: Sodium titanate nanoribbons with large interlayer spacing theoretically facilitate rapid transport of sodium ions. Particle retention system: negatively charged sodium titanate nanoribbons can form a particle retention system with cationic polyacrylamide (CPAM), which plays a good role in the retention and flocculation of paper materials and fillers in the papermaking process. And within a certain range, the larger its length, the more favorable it is for the flocculation of kaolin, but its own agglomeration effect will inhibit flocculation (there is a critical length value).}

^{Preparation of titanium dioxide nanoribbons: Sodium titanate nanoribbons can be converted into rutile TiO ¡ãCnanoribbons through hydrothermal treatment and other methods, and their phase transformation mechanism can be studied.}

^{Ion exchange and adsorption: It can utilize its layered structure and surface characteristics to perform ion exchange and adsorption on specific pollutant ions for purification treatment of water or air. However, further research and practical applications are needed in this area.}

^{Related Information}

^{Please e-mail for the detailed characterization data.}

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