Carbon nanofiber 

Single-walled carbon nanotubes (SWCNTs) are cylindrical structures made up of one layer of graphene. They have unique electrical and mechanical properties that make them attractive for use in various applications, such as electronics, energy storage, and sensors.

SWCNTs can be applied in the following fields:

 

Electronics: The high conductivity and semiconductor properties of SWCNTs make them ideal materials for manufacturing transistors, electrodes, and electronic devices.

 

Material reinforcement: Composite materials made from SWCNTs have extremely high strength and rigidity, making them suitable for producing lightweight, high-strength structural materials.

 

Energy storage: SWCNTs can be used as electrode materials for energy storage devices such as supercapacitors or lithium-ion batteries because they have high surface area-to-volume ratios, high electrical conductivity, and good chemical stability.

 

Biomedicine: SWCNTs also have extensive applications in biomedicine, such as drug delivery, therapy, and imaging. They can bind with biomolecules and penetrate cell membranes, while also emitting fluorescence signals in the near-infrared spectrum, making them ideal tools for biological imaging and detection.

 

Environmental protection: SWCNTs can be used to manufacture adsorbents that remove toxic and harmful substances from water and air.

  

Carbon nanotube fibers (CNT fibers) are macroscopic materials made up of aligned SWCNTs. They are strong and lightweight, making them potentially useful for structural applications like composites and textiles.

CNT fibers can be applied in the following fields:

Strength enhancement: CNT fibers are composed of thousands of nanoscale carbon tubes, which give them extremely high strength and rigidity. This makes CNT fibers an ideal choice for manufacturing high-performance materials in areas such as aerospace, sports equipment, and aviation.

Electric and thermal materials: Due to their excellent conductivity, CNT fibers can replace traditional metal wires such as copper wires in some applications. Additionally, CNT fibers can also be used as flexible heating elements.

Adsorbents: The large surface area of CNT fibers makes them suitable for use as adsorbents to remove pollutants from water and air, such as in water treatment and air filtration.

Biomedicine: CNT fibers also have extensive applications in biomedicine, such as tissue engineering, drug delivery, and biosensors. They can interact with biomolecules, enabling specific biomedical applications.

 

In summary, CNT fibers will play an important role in multiple fields based on their unique physical, chemical, and biological properties.

 

 

Carbon nanofibers (CNFs) are similar to CNTs but have a larger diameter and may have multiple layers of graphene. They can be produced by a variety of methods, including electrospinning and chemical vapor deposition. CNFs also have unique electrical and mechanical properties that make them suitable for use in applications like energy storage, catalysis, and biomedical engineering.

CNFs can be applied in the following fields:

 

Catalysts: Due to their numerous surface active sites, CNFs can serve as catalyst supports. In chemical reactions, they can provide high selectivity and reaction activity.

 

Energy storage: CNFs can be made into electrode materials for supercapacitors and lithium-ion batteries. Supercapacitors have high power density and long life, while lithium-ion batteries have high energy density and long cycle life.

 

Material reinforcement: CNFs can be mixed with various materials (such as polymers, metals, etc.) to prepare composite materials with higher strength and rigidity. These composite materials can be used in aerospace, automotive, medical devices, and other fields.

 

Environmental protection: CNFs can be used in water treatment to remove harmful pollutants. Additionally, they can be used in gas separation and air filtration.

 

Biomedicine: CNFs also have extensive applications in biomedicine, such as drug delivery, tissue engineering, and imaging. For example, CNFs can interact with biomolecules through surface modification, enabling specific biomedical applications.

 

In summary, CNFs will play an important role in multiple fields based on their unique physical, chemical, and biological properties.

 

Welcome to Aikerly customization