Surface DBD plasma microbubble reactor for degrading methylene blue
Surface DBD plasma microbubble reactor for degrading methylene blue
Water contaminants such as endocrine inhibitors, pharmaceuticals, and chlorine treatment by-products are only recently being identified as significant hazards to human health. Since current chlorine treatment does not address many of these compounds and conventional ozone processing is not seen as an economic alternative, water adjacent plasma treatment has been investigated as a more efficient and effective decontamination method. This work investigates the use of a surface dielectric barrier discharge electrode as a reduced discharge voltage portable plasma water treatment method. The gas passes through holes in the electrodes, normal to the discharge surface, so that the entire cross-sectional area of the feed gas is exposed to plasma, prior to passing through a hydrophobic filter and bubbling into the water. The decontamination effectiveness is quantified by measuring the degradation of methylene blue with absorption spectroscopy. Studies of the different processing parameters (treatment time, solution volume, initial concentration, electrode-filter distance, and gas flow rate) clarify the potential range of performance for this plasma treatment configuration. The setup has a yield energy of 0.45 g/kW·h at 25 ml of 1 mg/100 ml methylene blue treated over 5 minutes for a 92% degradation. The degradation rate is dependent upon the volume ratio of air to methylene blue solution, suggesting a first order chemical reaction process. The reaction rate is increased by increasing the quantity of either reactant. There is no change in the degradation between when the plasma is 1 mm or 1 cm from the water surface.
dielectric barrier discharge, non-thermal plasma, water treatment
Jakob, Henrike
aaeaf38d-e211-44d4-80a1-0d6f205152da
Paliwoda, Matthew
495a44fa-7e4b-4349-9802-d56e336fb43a
Rovey, Joshua L.
c65ab87d-0f5f-49fc-9c5d-3e268f5679d6
Kim, Minkwan
18ed9a6f-484f-4a7c-bf24-b630938c1acc
5 January 2023
Jakob, Henrike
aaeaf38d-e211-44d4-80a1-0d6f205152da
Paliwoda, Matthew
495a44fa-7e4b-4349-9802-d56e336fb43a
Rovey, Joshua L.
c65ab87d-0f5f-49fc-9c5d-3e268f5679d6
Kim, Minkwan
18ed9a6f-484f-4a7c-bf24-b630938c1acc
Jakob, Henrike, Paliwoda, Matthew, Rovey, Joshua L. and Kim, Minkwan
(2023)
Surface DBD plasma microbubble reactor for degrading methylene blue.
Physica Scripta, 98 (2), [025603].
(doi:10.1088/1402-4896/acad3b).
Abstract
Water contaminants such as endocrine inhibitors, pharmaceuticals, and chlorine treatment by-products are only recently being identified as significant hazards to human health. Since current chlorine treatment does not address many of these compounds and conventional ozone processing is not seen as an economic alternative, water adjacent plasma treatment has been investigated as a more efficient and effective decontamination method. This work investigates the use of a surface dielectric barrier discharge electrode as a reduced discharge voltage portable plasma water treatment method. The gas passes through holes in the electrodes, normal to the discharge surface, so that the entire cross-sectional area of the feed gas is exposed to plasma, prior to passing through a hydrophobic filter and bubbling into the water. The decontamination effectiveness is quantified by measuring the degradation of methylene blue with absorption spectroscopy. Studies of the different processing parameters (treatment time, solution volume, initial concentration, electrode-filter distance, and gas flow rate) clarify the potential range of performance for this plasma treatment configuration. The setup has a yield energy of 0.45 g/kW·h at 25 ml of 1 mg/100 ml methylene blue treated over 5 minutes for a 92% degradation. The degradation rate is dependent upon the volume ratio of air to methylene blue solution, suggesting a first order chemical reaction process. The reaction rate is increased by increasing the quantity of either reactant. There is no change in the degradation between when the plasma is 1 mm or 1 cm from the water surface.
Text
Jakob_2023_Phys._Scr._98_025603
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More information
Accepted/In Press date: 20 December 2022
Published date: 5 January 2023
Keywords:
dielectric barrier discharge, non-thermal plasma, water treatment
Identifiers
Local EPrints ID: 498616
URI: http://eprints.soton.ac.uk/id/eprint/498616
ISSN: 0031-8949
PURE UUID: 4ef254be-0138-476e-9794-cb9951a1485a
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Date deposited: 24 Feb 2025 17:40
Last modified: 22 Aug 2025 02:09
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Contributors
Author:
Henrike Jakob
Author:
Matthew Paliwoda
Author:
Joshua L. Rovey
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