Carbon Nanotube Wire, Diameter: 5-15 μm, Hardness: 1.0-1.5 Gpa

Product Details:

Material:

• Carbon Nanotube Wire:
  • Composed of aligned or spun carbon nanotubes (single-walled, multi-walled, or a hybrid).
  • Designed for high-strength, lightweight, and conductive applications.

Diameter:

• 5–15 μm:
  • Represents the overall wire diameter, suitable for applications requiring ultra-thin yet robust materials.

Hardness:

• 1.0–1.5 GPa:
  • Indicates exceptional mechanical hardness and resistance to deformation.
  • Comparable to high-performance engineering materials.

Tensile Strength:

• Likely ranges from 1–10 GPa (depending on the synthesis method and nanotube alignment).

Electrical Conductivity:

• Typically ~10⁵–10⁶ S/m:
  • Excellent for applications requiring high electrical conductivity with low weight.

Thermal Conductivity:

• In the range of 200–600 W/m·K:
  • Provides exceptional heat dissipation for thermal management applications.

Density:

• Typically around 1.3–1.6 g/cm³:
  • Lightweight material ideal for aerospace, automotive, and electronic industries.

Key Features:

1. High Strength-to-Weight Ratio:
   • Superior to steel and other metals for lightweight structural applications.
2. Exceptional Conductivity:
   • Highly conductive, making it suitable for electrical and thermal applications.
3. Durability:
   • Excellent mechanical stability under stress or high-temperature conditions.
4. Flexibility:
   • Retains strength and performance under bending or flexing.

Applications:

1. Electronics:
   • Used in ultra-thin, high-conductivity wires for microelectronics or flexible electronics.
   • Can replace copper in miniaturized circuits for reduced weight.
2. Aerospace and Automotive:
   • High-performance, lightweight wiring for weight-sensitive applications.
   • Heat-resistant cabling for critical systems.
3. Energy Transmission:
   • Used in power cables or conductive threads for wearable technology and smart textiles.
4. Medical Applications:
   • Thin and biocompatible wires for advanced medical devices or implants.
5. Advanced Composites:
   • Reinforces materials with high hardness and flexibility for engineering applications.

Advantages Over Traditional Materials:

• Lightweight: Much lighter than copper or steel.
• High Hardness and Durability: Withstands extreme mechanical and thermal stress.
• Eco-friendly: More sustainable due to carbon-based composition.