Nanoparticles: Carbon-Coated Iron [Fe-C]
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| Basic characteristics: | ||||||
|---|---|---|---|---|---|---|
| Name: | Carbon-Coated Iron | |||||
| Packaging: | Antistatic plastic bags | |||||
| Molecular Formula: | Fe-C | |||||
| Appearance: | Black powder | |||||
| Applications: | ||||||
| Microwave-absorption materials | Carbon-coated iron nanoparticles have the ability to absorb electromagnetic waves. They can be used as an absorbing material throughout the electromagnetic spectrum. This makes carbon-coated iron nanoparticles useful within military and commercial applications as a high-performance invisible material for absorbing extremely high frequency (EHF) millimeter wave (MMW), visible light and infrared. Its usefulness also extends to radioactive shielding for mobile phones and other devices. | |||||
| Magnetic-conductive paste | With high saturation magnetization and high magnetic conductivity, carbon-coated iron nanoparticles are well suited as a magnetic conductive paste for structural bonding material for small and complex magnetic heads. | |||||
| High-performance magnetic recording materials | With advantages including high coercivity, high saturation magnetization intensity (up to 1477km2/kg), signal-to-noise ratio and good oxidation resistance, carbon-coated iron nanoparticles improve performance of tape and large-capacity hard disks. | |||||
| Magnetic fluid | Magnetic fluid made of carbon-coated iron nanoparticles provides excellent properties. They are widely used in sealants, shock absorption materials, medical equipment and displays. | |||||
| Attributes: | ||||||
| Product name |
Average particle size [nm] |
Diameter Range [nm] |
Purity [%] |
Specific surface area [m2/g] |
Bulk density [g/cm3] |
Shape |
| Carbon_Coated Iron | 25 | <100 | 99+ | 30-50 | 0.10-0.25 | Round |
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| Carbon-coated iron nanoparticles | ||||||