Issue 39, 2012

Large-scale solution synthesis of α-AlF3·3H2O nanorods under low supersaturation conditions and their conversion to porous β-AlF3 nanorods

Abstract

We report for the first time the multi-gram scale solution growth of α-aluminium fluoride trihydrate (α-AlF3·3H2O) nanorods (NRs) under low supersaturation conditions, and their conversion to porous β-AlF3 NRs. Electron microscopy analysis shows that the NRs yielded from the optimized conditions have an average length of 1.9 μm and diameter of 223 nm. Nanoparticle morphology can also be achieved by tuning the supersaturation through several experimental parameters such as [Al3+] and [HF]/[Al3+] and H2O/2-propanol vol. ratio. Moderate thermal treatment of the as-synthesized α-AlF3·3H2O NRs in air atmosphere (5 h at 500 °C) results in pure β-AlF3 porous NRs, which may be useful as catalysts.

Graphical abstract: Large-scale solution synthesis of α-AlF3·3H2O nanorods under low supersaturation conditions and their conversion to porous β-AlF3 nanorods

Supplementary files

Article information

Article type
Paper
Submitted
12 Jun 2012
Accepted
10 Aug 2012
First published
13 Aug 2012

J. Mater. Chem., 2012,22, 20991-20997

Large-scale solution synthesis of α-AlF3·3H2O nanorods under low supersaturation conditions and their conversion to porous β-AlF3 nanorods

M. Estruga, F. Meng, L. Li, L. Chen, X. Li and S. Jin, J. Mater. Chem., 2012, 22, 20991 DOI: 10.1039/C2JM33782G

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