Fluorinated Carbon Nanotubes Description
Fluorinated Carbon Nanotubes are made from multi-walled carbon nanotubes and modified by fluorination. Materials with different properties from surface modification to deep fluorination can be customized according to customer requirements. Fluorinated carbon nanotubes have unique electrochemical properties. In addition, the surface can be modified by micro-fluorination to improve its hydrophilicity and improve the dispersion performance of carbon nanotubes in solution.
Fluorinated Carbon Nanotubes Specifications
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Form
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Off-white to black powder
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(CFx)n
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≥99 wt.%
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Fluorine content
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50~58 wt.%
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Free fluorine
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≤0.1 wt. %
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Metal impurity content
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≤100 ppm
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Diameter
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50±5nm
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Length
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10~20um
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Fluorinated Carbon Nanotubes Applications
Fluorinated Carbon Nanotubes have certain application potential in sensors, electronic devices, chips, and other fields.
Fluorinated Carbon Nanotubes Packaging
Our Fluorinated Carbon Nanotubes is carefully handled during storage and transportation to preserve the quality of our product in its original condition.
Fluorinated Carbon Nanotubes FAQs
Q1. What are Fluorinated Carbon Nanotubes?
Fluorinated carbon nanotubes (FCNTs) are carbon nanotubes (CNTs) that have been chemically modified by the addition of fluorine atoms. This fluorination process alters the surface properties of the CNTs, enhancing their chemical reactivity, solubility, and compatibility with various materials.
Q2. How are Fluorinated Carbon Nanotubes synthesized?
Fluorinated carbon nanotubes are typically synthesized through direct fluorination, where CNTs are exposed to fluorine gas at controlled temperatures. Another method involves using fluorine-containing compounds in a plasma or chemical reaction to introduce fluorine atoms onto the surface of the CNTs.
Q3. How does fluorination affect the electrical properties of carbon nanotubes?
Fluorination can modify the electrical properties of CNTs, typically reducing their conductivity due to the introduction of electron-withdrawing fluorine atoms. However, this modification can be tailored to achieve specific electrical characteristics needed for particular applications.
