Morphological and structural features of individual and composite nanooxides with alumina, silica, and titania in powders and aqueous suspensions

Morphological, structural, and adsorptive characteristics of such fumed oxides as alumina, silica, composite silica/alumina and alumina/silica/titania were studied using a variety of experimental methods. Heating of nanooxides caused several processes resulting in the temperature dependent structura...

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Published in:Powder technology 2009-11, Vol.195 (3), p.245-258
Main Authors: Gun'ko, V.M., Zarko, V.I., Turov, V.V., Oranska, O.I., Goncharuk, E.V., Nychiporuk, Y.M., Pakhlov, E.M., Yurchenko, G.R., Leboda, R., Skubiszewska-Zięba, J., Osovskii, V.D., Ptushinskii, Y.G., Derzhypolskyi, A.G., Melenevsky, D.A., Blitz, J.P.
Format: Article
Language:English
Subjects:
Adsorption
Applied sciences
Chemical engineering
Exact sciences and technology
Fumed alumina/silica/titania
Miscellaneous
Morphology
Nanoalumina
Nanosilica
Solid-solid systems
Structural characteristics
Water adsorption/desorption
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Summary:Morphological, structural, and adsorptive characteristics of such fumed oxides as alumina, silica, composite silica/alumina and alumina/silica/titania were studied using a variety of experimental methods. Heating of nanooxides caused several processes resulting in the temperature dependent structural changes of the materials because of changes in the amounts of intact and dissociatively adsorbed water not only at the surface of the nanoparticles but also in their volume that lead to changes in the oxide matrix structure. These processes dependent on the composition of nanooxides are much stronger for nanosilica than for alumina or composite oxides. The morphology of primary nanoparticles is more stable on different treatments than the structure of secondary and ternary particles. The amounts of water adsorbed onto the nanooxides from air correspond to the amounts of water strongly bound (unfrozen at T < 273 K) to the oxide surfaces in aqueous suspensions. Heating history can strongly affect many physicochemical properties of nanooxides, because of changes in the amounts of intact and dissociatively adsorbed water at the surface of nanoparticles and in their volume. [Display omitted]
ISSN:0032-5910
1873-328X
DOI:10.1016/j.powtec.2009.06.005