Ryunosuke Kondo scite author profile

Self-ordered porous alumina was fabricated via anodizing in an acid salt electrolyte solution, sodium hydrogen sulfate (NaHSO 4 ). High-purity aluminum specimens were anodized in a NaHSO 4 solution under various operating conditions with adjusted concentrations, temperatures, applied voltages, and times. Self-ordering was achieved via NaHSO 4 anodizing at appropriate applied voltages ranging from 20 to 28 V, and ordered cell arrangements with the cell size of 55-77 nm were successfully fabricated. Sulfur atoms originating from the electrolyte anions were incorporated into the ordered porous alumina. A honeycomb distribution consisting of a thick outer layer with a high concentration of sulfur and a very thin inner skeleton with a relatively low concentration sulfur was formed via NaHSO 4 anodizing. Our results suggested that there are now many electrolyte options for the fabrication of self-ordered porous alumina with a wide range of nanosizes.

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Advanced functional aluminum materials based on nanostructured surface

Kikuchi

Nakajima

Ikeda

et al. 2018

J.JILM

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Fabrication of Sticky and Slippery Superhydrophobic Aluminum Surfaces Covered with Nanostructured Anodic Oxide

et al. 2020

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Anodizing aluminum in a concentrated pyrophosphoric acid solution leads to the formation of numerous anodic alumina nanofibers, and this nanofiber-covered surface shows superhydrophilicity measuring less than 10° in water contact angle. In contrast, as the alumina surface is modified with a self-assembled monolayer (SAM), the surface exhibits superhydrophobicity measuring more than 150°. Herein, we demonstrate the fabrication of sticky and slippery superhydrophobic aluminum surfaces by optimizing the nanostructure of anodic alumina nanofibers. Commercially available 5N aluminum and 3004 aluminum alloy were anodized at a constant voltage of 75 V for up to 60 min for the formation of anodic alumina nanofibers on the surface. The specimens, then, were immersed in a 1.5 mM 3,3,4,4,5,5,6,6,7,7,8,8,8,-tridecafluorooctylphosphonic acid (FOPA)/ethanol solution at 313 K for 48 h to form SAMs on the surface of the anodic oxide. The sliding behavior of the water droplet formed on the anodized surface was examined by advancing and receding contact angle investigations. Numerous anodic alumina nanofibers and nanofiber-tangled intermetallic particles were formed on the aluminum surface by anodizing in pyrophosphoric acid. As the nanofiber-covered aluminum alloys were modified with fluorinated phosphonic acid SAMs, the aluminum surface exhibits a superhydrophobic behavior with contact angles of more than 170°. The sliding behavior of the water droplet was drastically changed with the anodizing time, and the highly sticky and slippery aluminum surfaces could be fabricated by controlling the structure of alumina nanofibers (Figure 1). A superhydrophobic aluminum surface with different wettabilities including sticky and slippery properties was fabricated by the selective anodizing process. Figure 1

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Ryunosuke Kondo

Superhydrophilic and superhydrophobic aluminum alloys fabricated via pyrophosphoric acid anodizing and fluorinated SAM modification

Fabrication of self-ordered porous alumina via anodizing in sulfate solutions

Advanced functional aluminum materials based on nanostructured surface

Fabrication of Sticky and Slippery Superhydrophobic Aluminum Surfaces Covered with Nanostructured Anodic Oxide

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