Titanate nanotubes

Product Name

^{Name:Titanate nanotubes}

Product Overview

^{Titanate nanotubes are a novel one-dimensional nanomaterial, first synthesized by Kasuga et al. using hydrothermal method in 1998. At present, research on titanium oxide nanotubes mainly focuses on optimizing preparation conditions, formation mechanisms, and practical applications. The preparation methods mainly include template method, anodizing method, and hydrothermal method. Among them, the titanium dioxide nanotubes produced by hydrothermal method have a smaller diameter, simple operation, low cost, and are conducive to industrial production. Currently, there are many studies being conducted. In terms of application, there are more studies on using titanium dioxide nanotubes as solar cell raw materials and catalyst carriers, while there are fewer studies on using them as photocatalytic materials to degrade pollutants.}

^{Technical Parameter}

^{Purity: 99%}

^{Diameter: 4-10 nm}

^{Length: 100-500 nm}

^{Specific surface area: 200-300 m2/g}

^{Shape: White powder}

^{Product Features}

^{Light energy conversion properties: capable of absorbing and converting light energy, providing potential applications for fields such as optoelectronic devices.}

^{Photocatalytic/electrochemical properties: It exhibits excellent catalytic activity in photocatalytic and electrocatalytic reactions and can be used in the degradation of organic pollutants, water splitting for hydrogen production, and other fields.}

^{Ionic exchange properties: It has ion exchange ability and can be used in fields such as ion exchange membranes and adsorption separation.}

^{Mechanical performance: Through specific assembly methods such as circular structure, it can have excellent compressive strength and high porosity, providing new solutions for separation, catalysis and other fields.}

^{Application Fields}

^{Solar cells: As an important component of photoelectric conversion materials, they can be applied in the manufacturing of efficient solar cells. Its nanotube structure not only provides a larger light absorption area, but also achieves higher electron transfer efficiency, thereby improving the photoelectric conversion efficiency.}

^{Catalyst: With rich active surfaces and catalytic activity, it can be used for the design and preparation of catalysts, and is widely used in fields such as environmental governance and energy conversion.}

^{Sensors: Due to their high surface area and sensitive response characteristics, they can be applied in fields such as gas sensors and photosensitive sensors to achieve high-precision detection of signals such as gases and light.}

^{Energy storage materials: The pore structure and high specific surface area give them excellent energy storage performance, which can be applied in fields such as supercapacitors.}

^{Biomedical: It has good biocompatibility and can be used for drug delivery, tissue engineering, and other applications in the biomedical field.}

^{Related Information}

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

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