Nanomaterials
Showing 65–80 of 276 results
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Conductive Carbon Black Nanoparticles in Water (C), ~150 nm, >99%, Plant as Raw Materials, 35wt%
Read moreConductive Carbon Black Nanoparticles in Water (C), ~150 nm, >99%, Plant as Raw Materials, 35wt%
It can be used for plastics, rubber, electronics technology, anti-static materials. It is all-natural, non-polluting material – It is the real green conductive material..
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Copper Nanoparticles (Co), >99%
Read moreCopper Nanoparticles (Co), >99%
“Acts as an anti-biotic, anti-microbial, and anti-fungal agent when added to plastics, coatings, and textiles
Copper diet supplements with efficient delivery characteristics
High strength metals and alloys
EMI shielding
Heat sinks and highly thermal conductive materials
Efficient catalyst for chemical reactions and for the synthesis of methanol and glycol
As sintering additives and capacitor materials
Conductive inks and pastes containing Cu Nanoparticless can be used as a substitute for very expensive noble metals used in printed electronics, displays, and transmissive conductive thin film applications
Superficial conductive coating processing of metal and non-ferrous metal
Production of MLCC internal electrode and other electronic components in electronic slurry for the miniaturization of microelectronic devices;
As nanometal lubricant additives”. -
Copper Nanoparticles (Co), ~25 nm, >99%
Read moreCopper Nanoparticles (Co), ~25 nm, >99%
“Acts as an anti-biotic, anti-microbial, and anti-fungal agent when added to plastics, coatings, and textiles
Copper diet supplements with efficient delivery characteristics
High strength metals and alloys
EMI shielding
Heat sinks and highly thermal conductive materials
Efficient catalyst for chemical reactions and for the synthesis of methanol and glycol
As sintering additives and capacitor materials
Conductive inks and pastes containing Cu Nanoparticless can be used as a substitute for very expensive noble metals used in printed electronics, displays, and transmissive conductive thin film applications
Superficial conductive coating processing of metal and non-ferrous metal
Production of MLCC internal electrode and other electronic components in electronic slurry for the miniaturization of microelectronic devices;
As nanometal lubricant additives”. -
Copper Nanoparticles (Co), ~50 nm, >99%
Read moreCopper Nanoparticles (Co), ~50 nm, >99%
“Acts as an anti-biotic, anti-microbial, and anti-fungal agent when added to plastics, coatings, and textiles
Copper diet supplements with efficient delivery characteristics
High strength metals and alloys
EMI shielding
Heat sinks and highly thermal conductive materials
Efficient catalyst for chemical reactions and for the synthesis of methanol and glycol
As sintering additives and capacitor materials
Conductive inks and pastes containing Cu Nanoparticless can be used as a substitute for very expensive noble metals used in printed electronics, displays, and transmissive conductive thin film applications
Superficial conductive coating processing of metal and non-ferrous metal
Production of MLCC internal electrode and other electronic components in electronic slurry for the miniaturization of microelectronic devices;
As nanometal lubricant additives”. -
Copper Oxide Nanoparticles (CuO), ~100 nm, >99%
Read moreCopper Oxide Nanoparticles (CuO), ~100 nm, >99%
“As burning rate catalyst in rocket propellant. It can greatly improve the homogeneous propellant burning rate, lower pressure index, and also perform better as a catalyst for the AP composite propellant
Can be applied to the catalyst, superconducting materials, thermoelectric materials, sensing materials, glass, ceramics and other fields
As ceramic resistors, magnetic storage media, gas sensors, near-infrared tilters, photoconductive and photothermal applications
As semiconductors, solar energy transformation, and high-tech superconductors.” -
Copper Oxide Nanoparticles (CuO), ~250 nm, >99%
Read moreCopper Oxide Nanoparticles (CuO), ~250 nm, >99%
“As burning rate catalyst in rocket propellant. It can greatly improve the homogeneous propellant burning rate, lower pressure index, and also perform better as a catalyst for the AP composite propellant
Can be applied to the catalyst, superconducting materials, thermoelectric materials, sensing materials, glass, ceramics and other fields
As ceramic resistors, magnetic storage media, gas sensors, near-infrared tilters, photoconductive and photothermal applications
As semiconductors, solar energy transformation, and high-tech superconductors.” -
Copper Oxide Nanoparticles (CuO), 50 nm, >99%
Read moreCopper Oxide Nanoparticles (CuO), 50 nm, >99%
“As burning rate catalyst in rocket propellant. It can greatly improve the homogeneous propellant burning rate, lower pressure index, and also perform better as a catalyst for the AP composite propellant
Can be applied to the catalyst, superconducting materials, thermoelectric materials, sensing materials, glass, ceramics and other fields
As ceramic resistors, magnetic storage media, gas sensors, near-infrared tilters, photoconductive and photothermal applications
As semiconductors, solar energy transformation, and high-tech superconductors.” -
Copper Oxide Nanoparticles in Water (CuO), ~25 nm, >99%, 10 wt%
Read moreCopper Oxide Nanoparticles in Water (CuO), ~25 nm, >99%, 10 wt%
“applied to the catalyst, superconducting materials, thermoelectric materials, sensing materials, glass, ceramics and other fields. In addition, the nano-copper oxide can be used as rocket propellant combustion catalyst. It not only can significantly improve the homogeneous propellant burning rate, lower pressure index, but also can better perform as the catalyst for the AP composite propellant. More use such as: Ceramic resistors, Gas sensors, Magnetic storage media, Near-infrared tilters, Photoconductive and photothermal applications, Semiconductors, Solar energy transformation, Catalysts, High-tech superconductors……
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Copper Oxide Nanoparticles in Water (CuO), ~250 nm, >99%, 10 wt%
Read moreCopper Oxide Nanoparticles in Water (CuO), ~250 nm, >99%, 10 wt%
“applied to the catalyst, superconducting materials, thermoelectric materials, sensing materials, glass, ceramics and other fields. In addition, the nano-copper oxide can be used as rocket propellant combustion catalyst. It not only can significantly improve the homogeneous propellant burning rate, lower pressure index, but also can better perform as the catalyst for the AP composite propellant. More use such as: Ceramic resistors, Gas sensors, Magnetic storage media, Near-infrared tilters, Photoconductive and photothermal applications, Semiconductors, Solar energy transformation, Catalysts, High-tech superconductors……
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Copper Oxide Nanoparticles in Water (CuO), ~50 nm, >99%, 10 wt%
Read moreCopper Oxide Nanoparticles in Water (CuO), ~50 nm, >99%, 10 wt%
“applied to the catalyst, superconducting materials, thermoelectric materials, sensing materials, glass, ceramics and other fields. In addition, the nano-copper oxide can be used as rocket propellant combustion catalyst. It not only can significantly improve the homogeneous propellant burning rate, lower pressure index, but also can better perform as the catalyst for the AP composite propellant. More use such as: Ceramic resistors, Gas sensors, Magnetic storage media, Near-infrared tilters, Photoconductive and photothermal applications, Semiconductors, Solar energy transformation, Catalysts, High-tech superconductors……
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Diamond Nanoparticles, ~10 nm, >99%
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Diamond Nanoparticles, ~100 nm, >99%
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Dysprosium Oxide Nanoparticles (Dy2O3), ~100 nm, >99%
Read moreDysprosium Oxide Nanoparticles (Dy2O3), ~100 nm, >99%
magnetic Nanoparticles with several applications. Dysprosium Oxide nanocrystals can also used as a high surface area for catalytic compounds.
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Dysprosium Oxide Nanoparticles (Dy2O3), 50 nm, >99%
Read moreDysprosium Oxide Nanoparticles (Dy2O3), 50 nm, >99%
magnetic Nanoparticles with several applications. Dysprosium Oxide nanocrystals can also used as a high surface area for catalytic compounds.
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Europium Oxide Nanoparticles (Er2O3), 50 nm, >99%
Read moreEuropium Oxide Nanoparticles (Er2O3), 50 nm, >99%
“Can be dispersed in glass or plastic for display purposes, such as display monitors
Can be surface modified for distribution into aqueous and non-aqueous media for bioimaging
High-temperature corrosion-resistant coatings
Dopants for optical fiber and laser materials
Tuned insulator for Josephson junctions
In up-conversion material, capacitors, and metal-Oxide-semiconductor transistors” -
Fe(III) Oxide Hydroxide / FeOOH Nanorods in Water (Fe2O3H2O), ~50 nm,x10 nm, >99%, Alpha, 20wt%
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