Enhanced Degradation of Pharmaceutical Compounds by a Microbubble Ozonation Process: Effects of Temperature, pH, and Humic Acids

This study systematically investigated the feasibility of the microbubble ozonation process to degrade the 17α-ethinylestradiol, ibuprofen, and atenolol through the comparison with the millibubble ozonation process for elucidating the degradation behavior and mechanisms during the microbubble ozonat...

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Bibliographic Details
Published in:Energies (Basel) 2019-11, Vol.12 (22), p.4373
Main Authors: Lee, Yong-Gu, Park, Yongeun, Lee, Gwanghee, Kim, Yeongkwan, Chon, Kangmin
Format: Article
Language:English
Subjects:
Activated carbon
Activated carbon adsorption
Aquatic ecosystems
Chemicals
Chlorine
Coagulation
Efficiency
Engineering
Entrepreneurs
Environmental engineering
Flocculation
Food industry
Free radicals
Gas detectors
Groundwater
Groundwater treatment
Humic acids
Membrane processes
microbubbles
millibubbles
oh radicals
Oxidation
Ozonation
Personal grooming
Pesticides
pharmaceutical compounds
Pharmaceuticals
Pollutant removal
Receiving waters
Rivers
Size effects
Sludge
Solubilization
Surface water
Temperature effects
Textile industry wastewaters
Wastewater
Wastewater treatment
Water treatment
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Summary:This study systematically investigated the feasibility of the microbubble ozonation process to degrade the 17α-ethinylestradiol, ibuprofen, and atenolol through the comparison with the millibubble ozonation process for elucidating the degradation behavior and mechanisms during the microbubble ozonation processes. The proportions of small microbubbles (diameter 1–25 μm) were increased with increasing the cavity pump frequency (40 Hz: 51.4%; 50 Hz: 57.5%; 60 Hz: 59.9%). The increased concentrations of O3 and OH radicals due to the higher specific area of O3 microbubbles compared to O3 millibubbles could facilitate their mass transfer at the gas–water interface. Furthermore, the elevated reactivity of O3 by increasing the temperature might improve the degradation of the pharmaceutical compounds, which was more pronounced for the microbubble ozonated waters than the millibubble ozonated waters. Although the degradation efficiency of the pharmaceutical compounds during the microbubble ozonation processes was significantly influenced by the existence of humic acids compared to the millibubble ozonation process, the increased solubilization rate of O3 and OH radicals by collapsing O3 microbubbles enhanced the degradation of the pharmaceutical compounds. Overall, these results clearly showed that the microbubble ozonation process could be an alternative option to conventional ozonation processes for the abatement of the pharmaceutical compounds.
ISSN:1996-1073
1996-1073
DOI:10.3390/en12224373