10.1021/acs.jpcc.5b09722.s004
Katsutoshi Nakayama
Katsutoshi
Nakayama
Etsushi Tsuji
Etsushi
Tsuji
Yoshitaka Aoki
Yoshitaka
Aoki
Soo-Gil Park
Soo-Gil
Park
Hiroki Habazaki
Hiroki
Habazaki
Control of Surface Wettability of Aluminum Mesh with
Hierarchical Surface Morphology by Monolayer Coating: From Superoleophobic
to Superhydrophilic
American Chemical Society
2015
Hierarchical Surface Morphology
noncoated mesh wetted
aluminum mesh
noncoated aluminum mesh
surface
nm
150 μ m mesh openings
2015-12-14 00:00:00
Media
https://acs.figshare.com/articles/media/Control_of_Surface_Wettability_of_Aluminum_Mesh_with_Hierarchical_Surface_Morphology_by_Monolayer_Coating_From_Superoleophobic_to_Superhydrophilic/2099734
This paper reports the formation
of hierarchically structured aluminum
mesh by a combination of simple chemical etching and anodizing. The
former introduced micrometer-sized etch pits, and the latter produced
nanopores of the order of 10 nm on the mesh with 150 μm mesh
openings. Coating the mesh with a monolayer of fluoroalkyl phosphate
made the surface superoleophobic to practically any liquid, including
hexane with a surface tension as low as 18.4 mN m<sup>–1</sup>. The hierarchical triple ∼100 μm/∼1 μm/∼10
nm pore surface morphology improved the superoleophobicity compared
to the dual ∼100 μm/∼10 nm and ∼1 μm/∼10
nm pore structures. When the aluminum mesh was coated with a fluorine-free
alkylphosphate monolayer, the surface was superhydrophobic, but superoleophilic.
The noncoated aluminum mesh was superhydrophilic and superoleophilic
with a liquid contact angle close to 0°. Using the aluminum mesh
with an alkylphosphate coating, a water/oil mixture was successfully
separated by allowing only the oil to pass through the mesh. In addition,
the mixture was separated using noncoated mesh wetted with water,
since oil was not able to pass through the mesh in this case.