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05.06.2018 | Composites

Microwave energy-based manufacturing of hollow carbon nanospheres decorated with carbon nanotubes or metal oxide nanowires

verfasst von: Selcuk Poyraz, Jonathan Cook, Zhen Liu, Lin Zhang, Amit Nautiyal, Britta Hohmann, Solveig Klamt, Xinyu Zhang

Erschienen in: Journal of Materials Science | Ausgabe 17/2018

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ABSTRACT

Nanostructured hollow carbon spheres (HCNSs), with either carbon nanotube (CNT) or metal oxide nanowire (MONW) decoration on their surface, were synthesized as building materials with a great potential for the next-generation advanced applications. A well-established, polymeric latex NS synthesis method and a simply modified version of a microwave (MW) energy-based carbonization approach, i.e., Poptube, were systematically combined to obtain these HCNSs. Through this simple, facile, affordable and easily scalable “combined synthesis method,” it was managed to successfully produce HCNSs with unique morphological, spectroscopic, thermal and elemental features, all of which were strongly supported by both various material characterization test results and the relevant previous literature data. Thus, it is believed that the as-synthesized CNT or MONW decorated HCNSs (CNT-MONW/HCNS) from the above-mentioned method would soon become the materials of preference for the next-generation advanced applications in various science and engineering fields.

Vorheriger Artikel Nacre-inspired lightweight and high-strength AZ91D/Mg2B2O5w composites prepared by ice templating and pressureless infiltration

Nächster Artikel Temperature-dependent longitudinal tensile strength model for short-fiber-reinforced polymer composites considering fiber orientation and fiber length distribution

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Titel: Microwave energy-based manufacturing of hollow carbon nanospheres decorated with carbon nanotubes or metal oxide nanowires
verfasst von: Selcuk Poyraz
Jonathan Cook
Zhen Liu
Lin Zhang
Amit Nautiyal
Britta Hohmann
Solveig Klamt
Xinyu Zhang
Publikationsdatum: 05.06.2018
Verlag: Springer US
Erschienen in: Journal of Materials Science / Ausgabe 17/2018
Print ISSN: 0022-2461
Elektronische ISSN: 1573-4803
DOI: https://doi.org/10.1007/s10853-018-2511-1

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