High Conductivity Single-Walled Carbon Nanotubes (SWCNTs)

Product Overview
High conductivity single-walled carbon nanotubes (SWCNTs) are seamless hollow tubes formed by rolling a single layer of graphite hexagonal lattice. These nanotubes possess extremely high electrical conductivity and outstanding mechanical properties. Due to their unique structure and electronic characteristics, they find broad applications across multiple high-tech fields. Manufactured using the floating catalytic chemical vapor deposition (FC-CVD) method, these SWCNTs offer exceptional purity and superior conductivity, making them ideal for applications in electronics, energy storage and conversion, sensors, and more.

Key Features

• Outstanding Conductivity: These high-conductivity SWCNTs boast an electrical conductivity exceeding 2000 s/cm, far surpassing regular single-walled carbon nanotubes.
• Unique Structure: Formed from a single layer of carbon atoms curled into a tubular structure, their nanoscale diameter imparts exceptional physical and chemical properties.

Applications

• Electronics: Used in integrated circuits as wires and transistors, these SWCNTs improve the performance and integration of electronic devices.
• Energy Storage and Conversion: They serve as electrode materials in lithium-ion batteries, supercapacitors, and other energy devices, enhancing charge-discharge performance and extending cycle life.
• Sensors: With their highly sensitive response to electrical signals, these SWCNTs are ideal for use in high-sensitivity chemical and biological sensors.
• Flexible Electronics: They can be used to fabricate flexible conductive films with excellent flexibility and conductivity, widely applied in wearable devices.
• New Energy Vehicles: These SWCNTs are used in battery electrodes to improve fast charging performance and extend driving range.