Abstract
Anodic aluminum oxide has unique and highly
attractive properties, including self-ordering of porous structure
during anodization. Although anodization regimes leading to
formation of highly ordered porous structures had been found
experimentally, many aspects of the self-organization mechanism
remain unsolved. Here, the detailed in situ small-angle X-ray
diffraction study of the self-ordering in porous alumina films is
reported. Structure evolution kinetics was deduced by a quantitative
analysis of diffraction patterns combined with electron
microscopy. The rate of pore ordering is shown to have maximal
value at the initial anodization stage and rapidly decreases
inversely proportional to t0.2. Self-organization is shown to occur via growth of domains possessing preferential in-plane orientation
and “death” of other domains, similar to Ostwald ripening governed by difference in pore growth rates for domains of different
orientations. The process is accompanied by pore death and splitting making a significant impact on anodic oxides utilization in any
mass-transport issues. This finding opens a novel approach for growth of highly ordered porous anodic oxide films.
Original language | English |
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Pages (from-to) | 23726-23731 |
Number of pages | 6 |
Journal | Journal of Physical Chemistry C |
Volume | 115 |
DOIs | |
Publication status | Published - 2011 |