Metal and Metal Alloy Nanoparticles

Metal and metal alloy nanoparticles are reshaping advanced materials by merging precision engineering with ecological responsibility. From enabling carbon-neutral manufacturing to purifying contaminated ecosystems, these materials offer scalable, low-energy solutions to global sustainability challenges. CD BioSustainable's products exemplify this potential, delivering measurable environmental and economic impacts across industries. As research progresses, smart alloy NPs will play an increasingly critical role in achieving net-zero emissions and circular economy goals.

Thermal Catalysis

Thermal catalysis accelerates chemical reactions at certain temperatures using catalysts and is widely applied in various fields. Metal oxide nanomaterials, with their high specific surface area, provide active sites and can act as carriers. Nano copper, due to its high surface activity and quantum size effects, stands out in oxidation-reduction reactions. Rhodium carbon is an important catalyst for hydrogenation reactions. Nitrides are suitable for high-temperature reactions, while carbides excel in electron transfer reactions. Mesoporous materials facilitate the diffusion of substances and can serve as catalyst carriers. Metal-organic frameworks, with their adjustable structures and high porosity, can function as catalysts or carriers.

Product Type	Product Name	Applications
Metal Oxide Nanomaterials	Cerium(III) oxide	Catalysis, polishing, glass, and ceramic materials
Nano Copper	Nano Copper	Conductive inks, plating, and catalysis
Zinc Carbonate	Zinc Carbonate	Fertilizers, pigments, and pharmaceuticals
Metal Oxide Nanomaterials	Nano Titanium(IV) oxide	Paints, coatings, and photocatalysis
Metal Oxide Nanomaterials	Nano Aluminum oxide	Abrasives, ceramics, and electronics
Metal Oxide Nanomaterials	Vanadium(V) oxide	Catalysts and chemical sensors
Nitride	Boron Nitride	Lubricants, ceramics, and electronics
Metal Oxide Nanomaterials	Nano Magnesium oxide	Refractory materials and electronics
Metal Oxide Nanomaterials	Nano Manganese dioxide	Batteries, catalysts, and electronics
Nitride	Silicon Nitride	Ceramics, bearings, and cutting tools
Carbide	Silicon Carbide	Abrasives, ceramics, and electronics
Mesoporous Material	Mesoporous Carbon	Energy storage, catalysis, and adsorption
Metal-Organic Framework Material	MCM-41 Molecular Sieve	Catalysis, adsorption, and separation
Mesoporous Material	Mesoporous SBA-15	Catalysis, adsorption, and separation
Metal-Organic Framework Material	ZSM-5	Catalysis, adsorption, and separation
Metal-Organic Framework Material	CMK-3	Catalysis, adsorption, and separation
Mesoporous Material	Mesoporous Silica	Drug delivery, catalysis, and adsorption
Mesoporous Material	Mesoporous Silica Microspheres	Drug delivery, catalysis, and adsorption
Mesoporous Material	Mesoporous Silica Nanoparticles	Drug delivery, catalysis, and adsorption
Mesoporous Material	Hollow Mesoporous Microspheres	Drug delivery, catalysis, and adsorption

Photocatalysis

Photocatalysis utilizes light to drive catalysts to initiate chemical reactions and is widely used in many fields. 2D materials, carbon nanotubes, carbon black, and other materials each have their own advantages. 2D materials, with their excellent electrical and optical properties, are conducive to photocatalytic reactions. Carbon nanotubes promote the transfer and separation of photogenerated electrons. Carbon black can act as a carrier. Graphene oxide can adjust the electronic structure. Reduced graphene oxide enhances conductivity. Nitrogen-doped graphene alters the electronic structure. Fullerene participates in carrier transmission and transformation. Metal oxide nanomaterials are commonly used as photocatalysts. Nitrides, mesoporous materials, quantum dots, carbides, and metal-organic frameworks all play key roles in different aspects of photocatalysis based on their respective characteristics.

Product Type	Product Name	Applications
2D Material	Tungsten Carbide (IV), 99.99%, ≥100 mesh	Wear-resistant coatings, cutting tools
2D Material	Black Phosphorus, 99.99%, Powder	Electronics, optoelectronics, energy storage
Carbon Material	Carbon Nanopowder, 97%, Test Grade, Nano Ceramic Powder	Electronics, materials science, medicine
Carbon Material	Carbon Nanopowder, 97%, Test Grade, Nano Ceramic Powder	Electronics, materials science, medicine
Carbon Nanotubes	Carbon Nanotubes, Single-walled, 95%, Test Grade, Diameter: <2 nm, Length: 1 - 3 μm	Electronics, composite materials, energy storage
Fullerene	Fullerene C60, 99.9%	Electronics, materials science, medicine
Graphite	Graphite, 98%, Test Grade, Thickness: 0.55 - 3.74 nm, Diameter: 0.5-3μm, Layers: <10/td>	Batteries, electrodes, lubricants
Graphite Black	Graphite Black	Lubricants, batteries, electrodes
Intermediary Material	Mesoporous Silica Nanoparticles, Diameter: 60-250 nm, Surface Area: 410-680 m²/g, Diameter: 2.8-13.3 nm, Pore Volume: 0.57-1.66 cm³/g	Drug delivery, catalysis, sensors
Metal Organic Framework	MCM-41 Molecular Sieve, Pore Size: 3 - 5 nm, Surface Area: ≥1000 m²/g	Gas separation, catalysis, sensors
Metal Organic Framework	ZSM-5 Molecular Sieve, Silica Ratio: ≥36, Surface Area: ≥340 m²/g	Catalysis, gas separation, sensors
Metal Organic Framework	Ordered Mesoporous Carbon CMK-3, Surface Area: ≥800 m²/g, Pore Size: 5 - 7 nm, Pore Volume: 1.0 - 1.5 cm³/g	Energy storage, catalysis, sensors
Metal Oxide Nanomaterials	Tungsten Oxide (IV), 99.995%	Electronics, catalysts, sensors
Metal Oxide Nanomaterials	Nano-scale Tungsten Oxide, Molybdenum Oxide	Electronics, catalysts, sensors
Metal Oxide Nanomaterials	Tungsten Trioxide (VI), 99.95%, Trace Metal Analysis, 50 nm	Electronics, catalysts, sensors
Nitride	Nitride, 99.5%, Trace Metal Analysis, ≤45 μm	Electronics, ceramics, coatings
Nitride	Nitride, 99.5%, Trace Metal Analysis, ≤45 μm	Electronics, ceramics, coatings
Nitrogen-Doped Graphene	Nitrogen-Doped Graphene, 98%, Surface Area: 100 - 300 m²/g, Layers: ≤3	Electronics, sensors, energy storage
Oxidized Graphene	Oxidized Graphene, 99%, Test Grade, Thickness: 0.55 - 1.2 nm, Diameter: 0.5 - 3 μm, Layers: <3	Electronics, sensors, energy storage
Quantum Dot Material	Tungsten Carbide	Electronics, displays, lighting
Reduced Graphene Oxide	Reduced Graphene Oxide, ≥98 wt%	Electronics, sensors, energy storage

Electrocatalysis

Electrocatalysis accelerates electrochemical reactions in an electric field with the help of catalysts and is of great significance in the fields of energy conversion and electrochemical synthesis. Carbon nanotubes, with their strong conductivity, large specific surface area, and chemical stability, can be used as electrode materials or carriers to promote reactions. Carbon black is conductive and has good adsorption properties, which can modify electrodes to enhance activity. Graphene oxide can be compounded to make high-performance catalysts. Graphene, with its excellent mechanical and electronic migration properties, can be used directly as an electrode or participate in composite catalysis. Nitrogen-doped graphene, with its altered electronic structure, has high catalytic activity for oxygen reduction. Reduced graphene oxide has good conductivity and is used in various battery electrodes. Fullerene, with its unique structure, plays a role in solar cells. Platinum black is an excellent catalyst but is costly. Nitrides and carbides can be used as electrodes or carriers, etc. 2D materials have potential in electrocatalytic hydrogen evolution and other reactions based on their characteristics.

Product Type	Product Name	Applications
2D Material	Black Phosphorus, 99.99%, Powder	Electronics, optoelectronics, energy storage, catalysis
Carbon Material	Carbon Nanopowder, 97%, Test Grade, Nano Ceramic Powder	Electronics, materials science, medicine, composite materials
Carbon Material	Carbon Nanopowder, 97%, Test Grade, Nano Ceramic Powder	Electronics, materials science, medicine, composite materials
Carbon Nanotubes	Carbon Nanotubes, Single-walled, 95%, Test Grade, Diameter: <2 nm, Length: 1 - 3 μm	Electronics, composite materials, energy storage, sensors
Fullerene	Fullerene C60, 99.9%	Electronics, materials science, medicine, lubricants
Graphite	Graphite, 98%, Test Grade, Thickness: 0.55 - 3.74 nm, Diameter: 0.5-3μm, Layers: <10/td>	Batteries, electrodes, lubricants, thermal management
Graphite Black	Graphite Black	Lubricants, batteries, electrodes, thermal management
Nitride	Nitride, 99.5%, Trace Metal Analysis, ≤45 μm	Electronics, ceramics, coatings, cutting tools
Nitrogen-Doped Graphene	Nitrogen-Doped Graphene, 98%, Surface Area: 100 - 300 m²/g, Layers: ≤3	Electronics, sensors, energy storage, catalysis
Oxidized Graphene	Oxidized Graphene, 99%, Test Grade, Thickness: 0.55 - 1.2 nm, Diameter: 0.5 - 3 μm, Layers: <3	Electronics, sensors, energy storage, composite materials
Platinum Black	Platinum Black, 20% Graphite Black (with surface active agent and no reaction)	Catalysts, electronics, sensors
Reduced Graphene Oxide	Reduced Graphene Oxide, ≥98 wt%	Electronics, sensors, energy storage, composite materials

Biomass Catalysis

Biomass catalysis uses catalysts to convert biomass resources into high-value products and is of great significance in the fields of renewable energy and green chemistry. Graphene, with its large specific surface area and good conductivity, can be used as a carrier to enhance the activity and stability of catalysts for hydrogenation reactions. Carbon nanotubes, with their unique structure, help with adsorption and transport, acting as carriers or promoters to accelerate pyrolysis and gasification. Graphitic carbon nitride has photocatalytic activity for photocatalytic transformation. Reduced graphene oxide improves the performance of electrocatalytic electrodes. Metal oxide nanomaterials are active components for catalytic oxidation and reforming. Nitrides participate in cracking and reforming to change reaction pathways. Mesoporous materials act as carriers to optimize reaction rates and lifetimes. Metal-organic frameworks, with their adjustable structures and rich active centers, are used in various stages of biomass to enhance overall utilization efficiency.

Product Type	Product Name	Applications
Carbon Nanotubes	Carbon Nanotubes, Single-walled, 95%, Test Grade, Diameter: <2 nm, Length: 1 - 3 μm	Electronics, composite materials, energy storage, sensors
Graphite	Graphite, 98%, Test Grade, Thickness: 0.55 - 3.74 nm, Diameter: 0.5-3μm, Layers: <10	Batteries, lubricants, electrodes, thermal management
Graphite Carbon Nitride	Graphite Carbon Nitride, 98%, Surface Area: 100 - 300 m²/g, Layers: ≤3	Electronics, sensors, energy storage, catalysis
Intermediary Material	Cubic Ia3d Intermediary Carbon, 99.6%, Surface Area: 500 m²/g, Pore Size: 3.2-6.6 nm, Pore Volume: 0.75-1.1 cm³/g	Drug delivery, catalysis, sensors
Metal Organic Framework	MCM-41 Molecular Sieve, Pore Size: 3 - 5 nm, Surface Area: ≥1000 m²/g	Gas separation, catalysis, sensors
Metal Organic Framework	Mesoporous Silica SBA-15, Diameter: 500-2000 nm, Surface Area: 700-1100 m²/g, Pore Size: 6-11 nm, Pore Volume: 0.6-1.3 cm³/g	Gas separation, catalysis, sensors
Metal Organic Framework	ZSM-5 Molecular Sieve, Silica-Alumina Ratio: ≥36, Surface Area: ≥340 m²/g	Catalysis, gas separation, sensors
Metal Oxide Nanomaterials	Tungsten Oxide (IV), 20% in H2O, Nanoparticle Dispersion, High pH, <5.0nm APS Number Equivalent, 20% in H2O	Electronics, catalysts, sensors, coatings
Metal Oxide Nanomaterials	Tungsten Trioxide (VI), 99.95%, Trace Metal Analysis, 50 nm	Electronics, catalysts, sensors, coatings
Metal Oxide Nanomaterials	Iron(III) Oxide, 99.5%, 20 nm	Electronics, catalysts, sensors, coatings
Metal Oxide Nanomaterials	Aluminum Oxide, 97%, γ-phase, Surface Area: 185 m²/g	Electronics, catalysts, sensors, coatings
Nitride	Nitride, 99.5%, Trace Metal Analysis, ≤45 μm	Electronics, ceramics, coatings, cutting tools
Reduced Graphene Oxide	Reduced Graphene Oxide, ≥98 wt%	Electronics, sensors, energy storage, composite materials

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