This study explores the effectiveness of GaaOs/UV-C photocatalysis for disinfecting recirculating aquaculture system (RAS) effluents, focusing on the inactivation of Enterococcus faecalis. After material characterization, the research optimized key parameters, including UV-C irradiation intensity, GaaOs dosage, and oxidant selection (peracetic acid and peroxymonosulfate). The GaaOs/UV-C/peracetic acid (PAA) system was identified as the most effective configuration, significantly enhancing disinfection kinetics and halving treatment time compared to the GaaOs/UV-C system alone. In contrast, the addition of potassium peroxymonosulfate (PMS) exhibited an antagonistic effect, indicating non-productive radical consumption pathways. Mechanistic considerations through scavenging experiments revealed that singlet oxygen (1Oa) played a dominant role in the bacterial disinfection for the GaaOs/UV-C system, while hydroxyl radicals (HO center dot) were the primary oxidative agents in the PAA-intensified process. The study confirmed the recyclability of GaaOs over multiple treatment cycles, showing sustained disinfection performance without significant loss of activity. Long-term assessments demonstrated fewer regrowth suppression in the Ga2O3/UV-C/PAA system, likely due to residual oxidants like peracetic acid and its by-products, which retain antibacterial properties post-treatment. Furthermore, validation in real aquaculture effluents confirmed the robust performance of the optimized systems, showcasing faster inactivation yields in fish tank water compared to simulated aquaculture water, attributed to differences in organic load. Toxicity considerations, featuring DBPs, water quality parameters measurement and phytotoxicity assessment, indicated promising results. This research positions GaaOs/UV-C photocatalysis, particularly when paired with PAA, as a technically viable and sustainable alternative to conventional chemical disinfectants for RAS applications.
This study explores the effectiveness of GaaOs/UV-C photocatalysis for disinfecting recirculating aquaculture system (RAS) effluents, focusing on the inactivation of Enterococcus faecalis. After material characterization, the research optimized key parameters, including UV-C irradiation intensity, GaaOs dosage, and oxidant selection (peracetic acid and peroxymonosulfate). The GaaOs/UV-C/peracetic acid (PAA) system was identified as the most effective configuration, significantly enhancing disinfection kinetics and halving treatment time compared to the GaaOs/UV-C system alone. In contrast, the addition of potassium peroxymonosulfate (PMS) exhibited an antagonistic effect, indicating non-productive radical consumption pathways. Mechanistic considerations through scavenging experiments revealed that singlet oxygen (1Oa) played a dominant role in the bacterial disinfection for the GaaOs/UV-C system, while hydroxyl radicals (HO center dot) were the primary oxidative agents in the PAA-intensified process. The study confirmed the recyclability of GaaOs over multiple treatment cycles, showing sustained disinfection performance without significant loss of activity. Long-term assessments demonstrated fewer regrowth suppression in the Ga2O3/UV-C/PAA system, likely due to residual oxidants like peracetic acid and its by-products, which retain antibacterial properties post-treatment. Furthermore, validation in real aquaculture effluents confirmed the robust performance of the optimized systems, showcasing faster inactivation yields in fish tank water compared to simulated aquaculture water, attributed to differences in organic load. Toxicity considerations, featuring DBPs, water quality parameters measurement and phytotoxicity assessment, indicated promising results. This research positions GaaOs/UV-C photocatalysis, particularly when paired with PAA, as a technically viable and sustainable alternative to conventional chemical disinfectants for RAS applications. Read More
Related posts:
Harnessing UV-C photoassisted AOPs: Amoxicillin degradation, disinfection by-products formation, and Enterococcus faecalis inactivation in aquaculture water
Visible-light-driven photocatalytic inactivation of Escherichia coli by titanium dioxide anchored on natural pyrite
Solar-assisted bacterial disinfection and removal of contaminants of emerging concern by Fe2+-activated HSO5- vs. S2O82- in drinking water
Photocatalytic activation of peroxymonosulfate using ilmenite (FeTiO3) for Enterococcus faecalis inactivation
Effect of the water matrix and reactor configuration on Enterococcus sp. inactivation by UV-A activated PMS or H2O2
Photocatalytic disinfection of wastewater using peroxymonosulfate activated by pyrite, chalcopyrite and marcasite under solar irradiation