Key Features

• Exceptional Mechanical Properties:These nanotubes offer extremely high strength and toughness, significantly enhancing the mechanical properties of composite materials.
• Outstanding Electrical Conductivity:They have excellent electrical conductivity, making them ideal for use in electronic components.
• Excellent Thermal Conductivity:With high thermal conductivity, they play a key role in thermal management applications.
• High Surface Area:A large surface area provides more active sites, ideal for catalysis and adsorption applications.
• Surface Functionalization:Carboxylation improves their ability to bond with various substrates or functional molecules, broadening their potential applications.

Applications

• Composite Materials:Used to improve the mechanical and electrical properties of plastics, rubber, and metal composites.
• Electronic Devices:Applied in the production of high-performance conductive inks, sensors, and flexible displays.
• Electrode Materials:Enhance energy storage capacity and power output efficiency in lithium-ion batteries and supercapacitors.
• Catalysts and Carriers:Provide more active sites for catalytic reactions or serve as catalyst supports.
• Energy Sector:Used in hydrogen storage materials and other renewable energy applications.
• Electromagnetic Shielding:Applied in electromagnetic wave absorption and military stealth technology.
• Biomedical:Serve as drug carriers, improving drug delivery efficiency and controlled release.
• Research:Used in scientific studies of nanomaterial properties and applications, supporting both basic and applied research.

Key Features

• Outstanding Mechanical Properties:Exceptional strength and toughness make them ideal for enhancing the mechanical performance of materials.
• Excellent Electrical Conductivity:High conductivity meets the demands of electronic devices and electrode materials.
• Superior Thermal Conductivity:Efficient heat transfer capabilities make them suitable for thermal management applications.
• Large Surface Area:Provides abundant active sites, making them suitable for catalysis and adsorption processes.

Applications

• Composite Materials:Enhance the strength and rigidity of plastics, rubber, and metals for high-performance composite production.
• Electronic Devices:Used in high-performance conductive inks, sensors, and flexible displays.
• Electrode Materials:Improve energy storage and output efficiency in lithium-ion batteries and supercapacitors.
• Catalysts and Carriers:Act as catalysts or supports, offering more active sites to boost catalytic efficiency.
• Energy Sector:Serve as hydrogen storage materials, supporting advancements in renewable energy technologies.
• Electromagnetic Shielding:Used in the production of materials for electromagnetic interference shielding and stealth applications.
• Biomedical Applications:Function as drug carriers, enhancing delivery efficiency and controlled release for biomedical research.
• Scientific Research:Widely applied in nanomaterials research, supporting interdisciplinary studies and innovations.

Key Features

• Superior Mechanical Properties:Exceptional strength and toughness make them suitable for enhancing the mechanical performance of composite materials.
• Outstanding Electrical Performance:Excellent conductivity meets the requirements for electronic devices and electrode materials.
• Efficient Thermal Conductivity:High thermal conductivity enables effective heat transfer for thermal management applications.
• Large Surface Area:Provides numerous active sites, ideal for catalysis and adsorption processes.
• Surface Functionalization:Hydroxylation enhances bonding with other materials, expanding their application range.

Applications

• Composite Materials:Improve the strength and toughness of plastic, rubber, and metal matrices for high-performance composite production.
• Electronic Devices:Used in high-performance conductive inks, sensors, and flexible displays.
• Electrode Materials:Boost energy storage and power output efficiency in lithium-ion batteries and supercapacitors.
• Catalysts and Carriers:Serve as catalysts or supports, offering more active sites to improve catalytic reaction efficiency.
• Energy Sector:Applied in hydrogen storage materials and other renewable energy technologies.
• Electromagnetic Shielding:Used in applications like wave absorption and stealth technology.
• Biomedical:Function as drug carriers, improving delivery efficiency and controlled release for biomedical research.
• Scientific Research:Widely used in the fundamental and applied research of nanomaterials, supporting interdisciplinary studies.

Key Features

• High Purity:Impurities are removed during high-temperature treatment, achieving a purity of >99.9%.
• Good Flexibility and Elasticity:Capable of withstanding significant deformation, making them suitable for micro-mechanical components.
• Exceptional Electrical Properties:Conductivity close to that of copper, exhibiting unique quantum conductance properties, ideal for nano-electronic devices.
• Excellent Thermal Properties:High thermal conductivity and stability, suitable for efficient heat dissipation materials.
• Strong Chemical Stability:High chemical stability, maintaining performance in most chemical environments, with the ability to undergo surface chemical modifications.
• Optical Properties:Unique optical absorption and emission characteristics, useful for optical sensors and light-emitting devices.

Applications

• Battery Electrodes:Can be used as a conductive agent in lithium-ion batteries, enhancing conductivity and cycle life.
• Composite Materials:Used to manufacture composites with high strength, conductivity, and thermal conductivity.
• Electronic Devices:Used in the development of integrated circuits and display backplane drivers.
• Sensors:Used in the production of high-sensitivity, fast-response gas sensors, biosensors, etc.
• Electric Heating Devices:Used to create efficient electric heating devices, leveraging their excellent conductivity and electrical-to-thermal conversion properties.

Key Features

• High Purity:High-temperature graphitization removes most metal impurities, achieving a purity of >99.9%.
• Good Flexibility and Elasticity:Capable of withstanding significant deformation without breaking, making them suitable for complex movements in micro-mechanical components.
• Excellent Electrical Properties:Conductivity close to copper, exhibiting quantum conductance properties, ideal for precise current control.
• Superior Thermal Properties:High thermal conductivity and stability, maintaining structural integrity at high temperatures, suitable for efficient heat dissipation materials.
• High Chemical Stability:Resistant to reactions in most chemical environments, with surface chemical modification capabilities to meet various application needs.
• Optical Properties:Unique optical absorption and emission characteristics, suitable for optical sensors and light-emitting devices.

Applications

• Battery Electrodes:Used as a conductive agent in lithium-ion batteries, enhancing conductivity and cycle life.
• Composite Materials:Enhances strength, conductivity, and thermal conductivity in composites that include graphitized carbon nanotubes.
• Electronic Devices:Utilized in the development of integrated circuits and display backplane drivers.
• Sensors:With high sensitivity and fast response, suitable for gas sensors, biosensors, etc.
• Electric Heating Devices:Used to create efficient electric heating devices, taking advantage of excellent conductivity and electrical-to-thermal conversion properties.

Key Features

• High Purity:High-temperature treatment removes most metal impurities, resulting in improved purity.
• Excellent Flexibility and Elasticity:Can withstand significant deformation without breaking, making them suitable for complex movements in micro-mechanical components.
• Outstanding Electrical Properties:Conductivity close to copper, exhibiting unique quantum conductance properties, ideal for precise current control.
• Superior Thermal Properties:High thermal conductivity, capable of efficiently transferring heat and maintaining structural stability at high temperatures, ideal for high-efficiency heat dissipation applications.
• High Chemical Stability:Resistant to reactions in most chemical environments, with surface chemical modification capabilities to meet various application requirements.
• Optical Properties:Unique optical absorption and emission characteristics in the near-infrared and visible light regions, suitable for optical sensors and light-emitting devices.

Applications

• Battery Electrodes:Used as a conductive agent in lithium-ion batteries to enhance conductivity and extend cycle life.
• Composite Materials:Used in polymer, metal, or ceramic matrices to create high-strength, highly conductive, and thermally efficient composite materials.
• Electronic Devices:Semiconductor-based integrated circuits and display backplane driver devices are being developed using graphitized carbon nanotubes.
• Sensor Devices:With high sensitivity and fast response, they are suitable for gas sensors, biosensors, and other applications.
• Electric Heating Devices:Utilized to manufacture efficient electric heating devices, benefiting from their excellent conductivity and electrical-to-thermal conversion properties.

Key Features

• Excellent Mechanical Properties:High strength and toughness, capable of withstanding significant mechanical stress.
• Outstanding Electrical Properties:Provides good electrical conductivity, suitable for electronic device applications.
• Good Thermal Properties:High thermal conductivity, efficiently transferring heat.
• Large Surface Area:Beneficial for applications in adsorption and catalysis.

Applications

• Composite Material Reinforcement:Enhances the mechanical properties of matrix materials, improving the strength and stiffness of plastics, rubbers, metals, and other materials.
• Electronic Devices:Used in manufacturing conductive inks, sensors, and flexible displays.
• Electrode Materials:Enhances energy storage and power output capabilities in lithium-ion batteries and supercapacitors.
• Catalysts and Catalyst Supports:Can serve as catalysts or catalyst supports to enhance the activity of catalytic reactions.
• Energy Sector:In addition to battery applications, it can be used in hydrogen storage materials.
• Wave Absorbing Materials:Used in military stealth and electromagnetic shielding applications, offering electromagnetic wave absorption capabilities.
• Biomedical Field:Used as drug carriers, effectively delivering drugs and improving sustained release effects.

Key Features

• Exceptional Mechanical Properties:Strength up to dozens or even hundreds of times greater than steel, with good toughness.
• Outstanding Electrical Properties:Good electrical conductivity, suitable for electronic device manufacturing.
• Good Thermal Properties:High thermal conductivity, capable of efficiently transferring heat.
• Large Surface Area:Provides more active sites, ideal for adsorption and catalysis applications.

Applications

• Composite Material Reinforcement:By adding carbon nanotubes to plastic, rubber, metal, and other matrices, mechanical properties of the materials are significantly enhanced.
• Electronic Devices:Used in manufacturing conductive inks, sensors, flexible displays, and other electronic components.
• Electrode Materials:As electrode materials for lithium batteries and supercapacitors, enhancing energy storage and power output capabilities.
• Catalysts and Catalyst Supports:Can be used as catalysts or catalyst supports, improving catalytic reaction performance.
• Energy Sector:Used in hydrogen storage materials, suitable for hydrogen gas storage applications.
• Wave Absorbing Materials:Used in the fabrication of wave-absorbing materials, with electromagnetic wave absorption capabilities, applied in military stealth and electromagnetic shielding.
• Biomedical Field:Used in drug delivery systems, capable of penetrating cell membranes and improving sustained drug release effects.

Key Features

• Enhanced Chemical Stability:Fluorinated carbon nanotubes exhibit stronger corrosion resistance, making them ideal for harsh chemical environments.
• Improved Wettability and Dispersion:Fluorination improves surface wettability and dispersion in solvents, facilitating further processing.
• Unique Thermal Properties:Fluorinated carbon nanotubes may possess excellent thermal conductivity and stability, suitable for thermal management applications.
• Good Mechanical Properties:Retains the high strength and modulus of the original carbon nanotubes, enhancing the mechanical properties of composite materials.
• Versatile Surface Functionalization:Can be further chemically modified to expand their application potential.

Applications

• Solid Lubricants:Fluorinated carbon nanotubes exhibit excellent lubricating properties, widely used in precision machinery and aerospace applications.
• Composite Materials:When combined with resins, ceramics, and other materials, they significantly enhance the mechanical properties and functionality of composite materials.
• Corrosion-Resistant Coatings:Due to their superior chemical stability, fluorinated carbon nanotubes are used in the production of anti-corrosion coatings to protect materials from degradation.

Key Features

• Excellent Mechanical Properties: Extremely high strength and toughness, with strength up to dozens or even hundreds of times that of steel.
• Outstanding Electrical Properties: Excellent conductivity, making them ideal for electronic devices and conductive materials.
• Good Thermal Properties: High thermal conductivity, ensuring efficient heat transfer.
• Large Surface Area: Suitable for applications like adsorption and catalysis, providing more active sites for reactions.

Applications

• Composite Material Reinforcement: Significantly enhances the strength and stiffness of materials such as plastics, rubbers, and metals, used in structural reinforcement and composite material manufacturing.
• Electronic Devices: Used in conductive inks, sensors, flexible displays, and other electronic devices.
• Electrode Materials: As electrodes in lithium-ion batteries and supercapacitors, improving energy storage and power output capabilities.
• Catalysts and Catalyst Supports: Used as catalysts or supports to enhance catalytic performance, widely applied in chemical catalysis and energy conversion fields.
• Energy Sector: Can serve as hydrogen storage materials, utilizing their hollow structure for hydrogen storage capacity.
• Electromagnetic Wave Absorption Materials: Used for electromagnetic wave absorption, suitable for stealth, shielding, and other military and industrial applications.
• Biomedicine: Used as drug carriers, improving drug delivery and controlled-release effects, with applications in biomedicine and therapy.
• Research: An important tool in nanomaterials research, widely used in scientific experiments and studies.