Home » Copper Oxide Nanoparticles Dispersion (CuO, Purity: 99.9 %, APS: 3-6 nm)
OXIDE DISPERSION
| Stock No. | CAS | MSDS | Specification | COA |
|---|---|---|---|---|
| NS6130-04-487 | 1317-38-0 |
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Copper Oxide Nanoparticles Dispersion
(CuO, Purity: 99.9 %, APS: 3-6 nm)
| Product | Copper Oxide Nanoparticles Dispersion | |
| Stock No | NS6130-04-487 | |
| CAS | 1317-38-0 | Confirm |
| APS | 3-6 nm | Confirm |
| Purity | 99.9% | Confirm |
| Molecular Formula | CuO | Confirm |
| Form | Dispersion | Confirm |
| Color | Black | Confirm |
| Boiling Point | < 120 °C | Confirm |
| pH value | 3 | Confirm |
| Concentration | 3 wt% | Confirm |
| Solvent | Isopropyl alcohol (IPA) | Confirm |
| Quality Control | Each lot of Copper Oxide Nanoparticles Dispersion was tested successfully. | |
| Main Inspect Verifier | Manager QC | |
Typical Chemical Analysis
| Assay | 99.9% |
Expert Reviews
Dr. Alte Schule Rheingau Ph.D, (Limerick Institute of Technology, Limerick, Ireland)
Copper oxide nanoparticles dispersion: Water pollution due to organic wastage from industrial production has become a serious problem in the world today. Most of the organic compounds in wastewater are toxic and cannot be decomposed naturally so they need to be treated with care before disposal. CuO is a promising candidate due to low cost and abundance As a p-type semiconductor of narrow bandgap in the visible region, CuO is expected to be a good material for application in photocatalyst and solar energy conversion.
Dr. Bunroeun Thong, Professor, (Phnom Penh Institute of Technology, Phnom Penh, Cambodia)
Cupric oxide (CuO) has been studied as a p-type semiconductor material with a narrow bandgap because of the natural abundance of its starting material, low-cost production processing, nontoxic nature, and its reasonably good electrical and optical properties.
Dr. Ms. Karel Gorissen, (Costa Rica Institute of Technology, Alajuela, Limon)
Copper oxide nanoparticles dispersion has other unique magnetic and superhydrophobic properties. These nanostructures show very promising applications in heterogeneous catalysis in the complete conversion of hydrocarbons into carbon dioxide, enhancement of thermal conductivity of nanofluids, monoenergetic materials, and super-hydrophobic surfaces or anode materials for lithium-ion batteries.
Dr. Ralph Bressler, (University of Southern Queensland, Australia)
Copper oxide nanoparticles dispersions have unique optical and semiconductor properties allowing the application of copper oxide nanoparticles in many industrial applications. Controlling the size and morphology of the nanoparticles enables the tunability of these properties. The major methods of synthesizing copper oxide nanoparticles dispersions involve one phase in either a batch or a continuous flow reactor.
Copper Oxide Nanoparticles Dispersion
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Dr. Alan Crawford Ph.D, (National Metallurgical Academy of Ukraine, Dnipropetrovsk, Ukraine)
Copper oxide nanoparticles dispersions are of great interest due to its potential applications in a wide variety of areas including electronic and optoelectronic devices, such as microelectromechanical systems, field-effect transistors, electrochemical cells, gas sensors, magnetic storage media, solar cells, field emitters, and nanodevices for catalysis.