Active gas replenishment and sensing of the wetting state in a submerged superhydrophobic surface
Active gas replenishment and sensing of the wetting state in a submerged superhydrophobic surface
Previously superhydrophobic surfaces have demonstrated effective drag reduction by trapping a lubricious gas layer on the surface with micron-sized hydrophobic features. However, prolonged reduction of drag is hindered by the dissolution of the gas into the surrounding water. This paper demonstrates a novel combination of superhydrophobic surface design and electrochemical control methods which allow quick determination of the wetted area and a gas replenishment mechanism to maintain the desirable gas filled state. Electrochemical impedance spectroscopy is used to measure the capacitance of the surface which is shown to be proportional to the solid/liquid interface area. To maintain a full gas coverage for prolonged periods the surface is held at an electrical potential which leads to hydrogen evolution. In the desired gas filled state the water does not touch the metallic area of the surface, however after gas has dissolved the water touches the metal which closes the electrochemical circuit causing hydrogen to be produced replenishing the gas in the surface and returning to the gas filled state; in this way the system is self-actuating. This type of surface and electrochemical control shows promise for applications where the gas filled state of superhydrophobic surfaces must be maintained when submerged for long periods of time.
1413-1419
Lloyd, Ben
97861a48-7b44-4bee-9962-e19e01ff3404
Bartlett, Philip
d99446db-a59d-4f89-96eb-f64b5d8bb075
Wood, Robert
d9523d31-41a8-459a-8831-70e29ffe8a73
21 February 2017
Lloyd, Ben
97861a48-7b44-4bee-9962-e19e01ff3404
Bartlett, Philip
d99446db-a59d-4f89-96eb-f64b5d8bb075
Wood, Robert
d9523d31-41a8-459a-8831-70e29ffe8a73
Lloyd, Ben, Bartlett, Philip and Wood, Robert
(2017)
Active gas replenishment and sensing of the wetting state in a submerged superhydrophobic surface.
Soft Matter, 13 (7), .
(doi:10.1039/C6SM02820A).
Abstract
Previously superhydrophobic surfaces have demonstrated effective drag reduction by trapping a lubricious gas layer on the surface with micron-sized hydrophobic features. However, prolonged reduction of drag is hindered by the dissolution of the gas into the surrounding water. This paper demonstrates a novel combination of superhydrophobic surface design and electrochemical control methods which allow quick determination of the wetted area and a gas replenishment mechanism to maintain the desirable gas filled state. Electrochemical impedance spectroscopy is used to measure the capacitance of the surface which is shown to be proportional to the solid/liquid interface area. To maintain a full gas coverage for prolonged periods the surface is held at an electrical potential which leads to hydrogen evolution. In the desired gas filled state the water does not touch the metallic area of the surface, however after gas has dissolved the water touches the metal which closes the electrochemical circuit causing hydrogen to be produced replenishing the gas in the surface and returning to the gas filled state; in this way the system is self-actuating. This type of surface and electrochemical control shows promise for applications where the gas filled state of superhydrophobic surfaces must be maintained when submerged for long periods of time.
Text
Corrected Manuscript.pdf
- Accepted Manuscript
More information
Accepted/In Press date: 8 January 2017
e-pub ahead of print date: 9 January 2017
Published date: 21 February 2017
Organisations:
Electrochemistry, nCATS Group
Identifiers
Local EPrints ID: 405799
URI: http://eprints.soton.ac.uk/id/eprint/405799
ISSN: 1744-683X
PURE UUID: 942e83dc-d56d-42b5-95e8-d141baefaed1
Catalogue record
Date deposited: 18 Feb 2017 00:20
Last modified: 16 Mar 2024 05:02
Export record
Altmetrics
Contributors
Author:
Ben Lloyd
Download statistics
Downloads from ePrints over the past year. Other digital versions may also be available to download e.g. from the publisher's website.
View more statistics
