Liquid-Feed Flame Spray Pyrolysis of Metalloorganic and Inorganic Alumina Sources in the Production of Nanoalumina Powders

Liquid-Feed Flame Spray Pyrolysis of Metalloorganic and Inorganic Alumina Sources in the Production of Nanoalumina Powders

Liquid-feed flame spray pyrolysis (LFFSP) of metalloorganic [N(CH2CH2O)3Al, alumatrane, and Al(Acac)3] and inorganic alumina [AlCl3 and Al(NO3)3·9H2O] precursors dissolved in 1:1 ethanol/THF, aerosolized with O2 and ignited can produce quite different alumina nanopowders during the ensuing combustio...

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Bibliographic Details
Published in:Chemistry of materials Vol. 16; no. 1; pp. 21 - 30
Main Authors: Hinklin, T, Toury, B, Gervais, C, Babonneau, F, Gislason, J. J, Morton, R. W, Laine, R. M
Format: Journal Article
Language:English
Published: American Chemical Society 13-01-2004
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Summary:Liquid-feed flame spray pyrolysis (LFFSP) of metalloorganic [N(CH2CH2O)3Al, alumatrane, and Al(Acac)3] and inorganic alumina [AlCl3 and Al(NO3)3·9H2O] precursors dissolved in 1:1 ethanol/THF, aerosolized with O2 and ignited can produce quite different alumina nanopowders during the ensuing combustion process. The metalloorganics appear to volatilize and combust easily to give nano-alumina, with particle sizes <20 nm and corresponding surface areas of ≈60 m2/g at rates of 50 g/h. In contrast, the nitrate appears to melt during combustion rather than volatilize, forming large, hollow particles typical of a spray pyrolysis process with particle sizes >70 nm and surface areas of ≈12 m2/g. AlCl3 appears to volatilize easily but does not hydrolyze rapidly in the flame leading to mixtures of alumina and recovered AlCl3. The resulting nanopowders consist of a mixture of transition alumina phases, primarily δ*, that could only be successfully identified and quantified by Rietveld refinement. Because the δ phase is not typically made as a high-surface-area material or in large quantities, it offers the opportunity to serve as a novel catalyst support. On heating to 1000 °C, the dominant phase becomes θ-Al2O3 that was clearly identified by 27Al MAS NMR using ab initio calculations of the 27Al NMR parameters derived from the X-ray structure. At present, the exact mechanism(s) whereby particles nucleate and grow, and phases form from the species generated during combustion, remains unknown.
Bibliography:ark:/67375/TPS-GXG7WD23-D
istex:3EDF7E19E4CCE2FA26DE7AF5782FF6CFB86B1C87
ISSN:0897-4756
1520-5002
DOI:10.1021/cm021782t