Key Features

• Hollow Structure:The outer carbon shell surrounds a hollow interior, providing a large internal space that is ideal for housing other substances.
• Low Density:The hollow interior gives the material a low overall density, making it suitable for lightweight applications.
• Excellent Thermal Stability:It maintains a stable structure at high temperatures, making it suitable for high-temperature applications.

Applications

• Energy Storage:Used as an anode material in lithium-ion batteries, hollow carbon spheres can buffer the volume change during lithium-ion insertion and extraction, improving battery stability and performance.
• Catalyst Support:The high surface area and unique structure make it an excellent support for catalytic active components, enhancing catalytic efficiency.
• Drug Delivery:The hollow core can encapsulate drug molecules, enabling controlled release and improving therapeutic efficacy.
• Adsorption & Separation:Exhibiting excellent adsorption properties, it is used for separating and purifying specific substances.
• Fuel Cells:Used as a support for oxygen reduction catalysts in fuel cells, enhancing cell performance.
• Pesticide Controlled Release:Exploiting its response to infrared light, hollow carbon spheres can be used for controlled pesticide release, improving agricultural efficiency.

Key Features

• Hollow Structure:The outer shell is made of carbon layers, while the interior is hollow, providing abundant space for storage or adsorption.
• Low Density:The hollow structure results in a relatively low overall density, which enhances the material’s suitability for lightweight applications.
• Good Thermal Stability:These spheres maintain their structural integrity even at elevated temperatures, making them ideal for high-temperature applications.

Applications

• Energy Storage:Used as an anode material in lithium-ion batteries, they improve cycling stability and rate performance.
• Catalyst Carrier:With a high surface area and unique structure, hollow carbon spheres serve as excellent catalyst supports, enhancing catalytic efficiency.
• Drug Carrier:The internal hollow space can store drug molecules, enabling controlled release applications.
• Adsorption and Separation:Suitable for adsorbing specific substances, they are useful in separation and purification processes.
• Fuel Cells:Hollow carbon spheres can serve as supports for oxygen reduction catalysts, improving fuel cell performance.
• Pesticide Controlled Release:In pesticide delivery systems, hollow carbon spheres respond to infrared light, enabling controlled release and enhancing pesticide utilization.

Key Features

• High Specific Surface Area:The large surface area makes these spheres ideal for adsorption, catalysis, and other high-performance applications.
• High Porosity:The internal pore space provides greater capacity for molecular storage and transport.
• Tunable Pore Size and Particle Size:During the preparation process, the pore size and particle size can be controlled to meet specific application needs.
• Excellent Chemical and Mechanical Stability:These spheres maintain outstanding stability even in harsh environments.
• Unique Hollow Structure:The hollow interior and radial pore channels offer significant advantages in molecular transport.

Applications

• Biomedicine:Due to their high specific surface area and good biocompatibility, these spheres are suitable for use as drug carriers, sensors, and other biomedical materials.
• Energy Storage and Conversion:Used in supercapacitors, lithium-sulfur batteries, and other energy storage devices, they enhance battery performance.
• Environmental Remediation:With excellent chemical stability and mechanical properties, these spheres are effective for air purification and water treatment.
• Catalysis:The unique hollow structure and high surface area make them ideal for use in catalytic reactions.
• Electrochemical Detection:For applications such as nicotine electrochemical detection, these spheres can improve electrode sensitivity and selectivity.

Key Features

• High Specific Surface Area:FDU-15 offers a specific surface area greater than 600 m²/g, providing abundant active sites for various applications.
• Precise Pore Size Control:The pore size is tightly controlled in the range of 4-6 nm, suitable for fast material transport and efficient adsorption.
• Ordered Pore Structure:The highly ordered pore channels provide stable and uniform pathways for material transport.

Applications

• Catalyst Support:FDU-15’s high surface area and uniform pore size distribution make it an excellent support for catalytic active sites, enhancing catalytic efficiency.
• Capacitor Electrodes:In electrochemical applications, FDU-15 is used as an electrode material for capacitors, delivering excellent energy storage performance.
• Nanoreactor:Its ordered structure makes FDU-15 an ideal candidate for use as a nanoreactor support, improving reaction efficiency in various processes.
• Macromolecule Adsorption:The pore structure of FDU-15 is well-suited for adsorbing large molecular substances, making it widely used in molecular separation and purification.
• Energy and Hydrogen Storage:As a storage material, FDU-15 offers high efficiency for energy and hydrogen storage, playing a key role in energy storage and release.

Key Features

• Ordered Mesoporous Structure:The pore arrangement is highly uniform, providing an ideal porous structure.
• High Surface Area:Typically greater than 500 m²/g, offering more active sites for various applications.
• Good Thermal and Chemical Stability:Optimized synthesis processes grant CMK-3 excellent thermal and chemical stability, making it resistant to corrosion and oxidation.

Applications

• Catalyst Support:The high surface area and tunable pore size make CMK-3 an ideal catalyst support material, enhancing the dispersion and catalytic efficiency of catalysts.
• Supercapacitor Electrodes:With its high surface area and excellent electrochemical properties, CMK-3 can be used as an electrode material for supercapacitors, providing high energy density and long cycle life.
• Drug Delivery:The porous structure of CMK-3 makes it an ideal carrier for controlled drug release and targeted drug delivery.
• Nanoreactors:In nanotechnology, CMK-3 can serve as a carrier for nanoreactors, facilitating chemical reactions at the nanoscale.
• Macromolecule Adsorption:CMK-3 is suitable for the adsorption of macromolecules, effectively capturing various large molecules.
• Biosensors:CMK-3 can be used in the construction of biosensors, significantly improving sensor sensitivity and selectivity.

Key Features

• High Specific Surface Area:Provides more contact sites, enhancing reactivity and adsorption capacity.
• Chemical Stability:Exhibits high stability in various chemical environments.
• Irregular Pore Structure:The pores are randomly distributed, lacking clear periodicity or symmetry.
• Broad Pore Size Distribution:The pore size is widely distributed, making it suitable for different applications.

Applications

• Energy Storage:Can be used in supercapacitors, lithium-ion batteries, and other energy storage devices, helping improve electrode material performance.
• Catalysis:Serves as a catalyst or catalyst support, enhancing catalytic efficiency.
• Gas Adsorption and Separation:Exhibits gas adsorption capabilities, suitable for gas storage, separation, and purification applications.
• Chemical Purification:Used in chemical substance purification and separation processes.
• Environmental Applications:Contributes to environmental pollution control, providing solutions for waste treatment and other environmental issues.

Key Features

• High Surface Area:Provides a large number of adsorption sites, enhancing the material’s adsorption capacity.
• Well-developed Pore Structure:Facilitates the diffusion and transport of adsorbate molecules, improving adsorption efficiency.
• Excellent Adsorption Performance:Demonstrates significant removal effects for organic compounds, heavy metal ions, residual chlorine, and other harmful substances.

Applications

• Wastewater Treatment:Efficiently removes organic compounds, heavy metals, residual chlorine, and other harmful substances from water.
• Water Purification:Improves water quality and ensures safe drinking water.
• Air Purification:Adsorbs harmful gases and particulate matter in the air, improving air quality.
• Drug Separation:Plays a key role in the separation and purification of pharmaceutical compounds.
• Drug Carriers:Acts as a carrier for drug delivery systems, enabling targeted release and controlled release of drugs.

Key Features

• High Specific Surface Area:The hollow structure results in an exceptionally high surface area, boosting active site density and electrochemical performance.
• Excellent Conductivity and Thermal Stability:The graphite shell provides outstanding conductivity and chemical stability, making them advantageous in energy storage and conversion applications.
• Tunable Electronic Structure:By doping with elements like nitrogen and oxygen, the electrochemical performance of carbon nanocages can be further optimized.
• Multifunctionality:In addition to being used as electrode materials, carbon nanocages also serve as effective catalyst supports, enhancing catalyst stability and activity.

Applications

• Electrochemical Energy Storage and Conversion:Used in lithium-ion batteries, supercapacitors, and fuel cells as electrode materials or catalyst supports, improving energy density and charge/discharge rates.
• Catalyst Supports:With their high specific surface area and excellent conductivity, carbon nanocages are widely employed as supports for catalysts, improving catalyst dispersion and stability.
• Photothermal Catalysis:Nitrogen-doped carbon nanocages exhibit outstanding performance in photothermal CO2 catalysis, enhancing photothermal conversion efficiency.
• Wave Absorption Materials:Carbon nanocages, with optimized impedance characteristics and large volume filling rates, serve as efficient wave-absorbing materials.

Key Features

• Excellent Electrical Conductivity:CNFs offer excellent electrical conductivity, making them ideal for electrochemical applications such as supercapacitor electrodes.
• Chemical Stability:CNFs maintain their structural and chemical integrity under various environmental conditions, offering high chemical stability.
• Unique Morphology:The petal-like structure provides a high density of active sites, enhancing their performance and potential across various applications.

Applications

• Energy Storage:CNFs are widely used in energy storage devices like lithium-sulfur batteries and supercapacitors, improving energy storage efficiency.
• Gas Adsorption and Separation:CNFs can effectively adsorb harmful gas molecules in applications such as air purification and industrial gas treatment, contributing to environmental protection.
• Biomedical Applications:CNFs are utilized in drug delivery systems and biosensors, significantly improving treatment efficacy and detection sensitivity.

Key Features

• Excellent Mechanical Properties:Solid carbon microspheres have outstanding mechanical performance, capable of withstanding pressure and wear.
• Electrical Conductivity:The good electrical conductivity makes them ideal for applications in electronic devices, electrode materials, and more.
• Thermal Stability:They maintain structural integrity even under high-temperature conditions, remaining stable up to 400°C.
• Chemical Stability:With excellent chemical resistance, these microspheres can endure exposure to various chemicals, extending their service life.

Applications

• Metallurgical Industry:In the electric arc furnace steelmaking slag-forming process, carbon microspheres react with oxygen to rapidly form a foam slag layer, effectively maintaining furnace temperature, enhancing smelting efficiency, and saving energy.
• Electronic Devices:Their conductivity and stability make them ideal for electrode materials, capacitors, and other electronic components.
• Environmental Protection:Used as adsorbents for removing heavy metal ions, organic pollutants, and other harmful substances, carbon microspheres play a crucial role in environmental remediation.
• Biomedicine:In biomedicine, carbon microspheres can serve as drug carriers, sensor materials, and more, providing innovative solutions in various medical applications.