Production of nanosized aluminum powders and their application as fillers for composite materials based on ultrahigh molecular weight polyethylene (UHMWPE)

Production of nanosized aluminum powders and their application as fillers for composite materials based on ultrahigh molecular weight polyethylene (UHMWPE)

A modified levitation-in-flow Gen-Miller technique is developed to produce nanodisperse aluminum particles 40–200 nm in size with a barrier coating of controlled thickness made of aluminum oxides and (oxy)nitrides for the use as a dielectric filler in composite materials. The polymerization filling...

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Veröffentlicht in:Bulletin of the Russian Academy of Sciences. Physics 2011-11, Vol.75 (11), p.1488-1494
Hauptverfasser: Zhigach, A. N., Berezkina, N. G., Leipunskii, I. O., Kuskov, M. L., Zotova, E. S., Kudrov, B. V., Novokshonova, L. A., Kudinova, O. I., Artemov, V. V., Zhigalina, O. M.
Format: Artikel
Sprache:eng
Schlagworte:
Aluminum
Aluminum oxide
Brittleness
Ceramics
Composite materials
Dielectric properties
Electron microscopy
Fillers
Hadrons
Heat transfer
Heat transmission
Heavy Ions
Levitation
Nanocomposites
Nitrides
Nuclear Physics
Oxides
Particle physics
Particulate composites
Physics
Physics and Astronomy
Plastic properties
Polymer matrix composites
Polymerization
Proceedings of the 9th All-Russia Conference “Physicochemistry of Superdispersed Nanosystems”
Synthesis
Ultra high molecular weight polyethylene
X-ray diffraction
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Zusammenfassung:A modified levitation-in-flow Gen-Miller technique is developed to produce nanodisperse aluminum particles 40–200 nm in size with a barrier coating of controlled thickness made of aluminum oxides and (oxy)nitrides for the use as a dielectric filler in composite materials. The polymerization filling technique (in situ polymerization) is used to synthesize new highly filled nanocomposite materials based on UHMWPE and nanodisperse aluminum with the barrier coating combining dielectric, heat-conducting, and plastic properties, which can replace brittle ceramics in a number of fields. The samples of such nanocomposites with a content of nanoaluminum ranging from 20 to 80 wt % were synthesized and characterized by electron microscopy and X-ray diffraction analysis.
ISSN:1062-8738
1934-9432
DOI:10.3103/S1062873811110293