کد مقاله | کد نشریه | سال انتشار | مقاله انگلیسی | نسخه تمام متن |
---|---|---|---|---|
5746567 | 1618792 | 2017 | 10 صفحه PDF | دانلود رایگان |
- A biofilm system was used to treat municipal waste water containing alkyl parabens.
- Paraben, BOD, COD and TOC removals increased as HRT increased.
- Competition occurred when waste water contained low concentration level of parabens.
- Co-metabolism occurred in the presence of high concentration level of parabens.
- The mineralization was enhanced with increasing HRT due to oxygenase production.
The enhanced removal of organic material from municipal waste water containing 50Â mg/L of chemical oxygen demand and a given amount of alkyl paraben using a biofilm system was investigated. The parabens used were methyl, ethyl, and propyl paraben. The experiments were conducted at influent paraben concentrations of 10 and 50Â mg/L. The influent pH was measured around 4.6 because of paraben hydrolysis. The effluent pH increased due to hydrogen consumption and small molecular acid generation. The higher removal rates were observed for the paraben with longer alkyl chains, which were more hydrophobic and capable of penetrating into microbial cells. The co-existing organic constituents in municipal waste water were found to be competitive with paraben molecules for microbial degradation at low paraben loading (i.e., 10Â mg/L). Instead, the co-metabolic effect was observed at a higher paraben loading (i.e., 50Â mg/L) due to more active enzymatic catalysis, implying the possible enhancement or organic removal in the presence of high levels of parabens. The difference in BOD and TOC removing ratios for parabens decreased with increasing HRT, implying their better mineralization than that of municipal organic constituents. This was because the microbial organism became more adapted to the reacting system with longer HRT, and more oxygenase was produced to facilitate the catechol formation and ring-opening reactions, causing apparent enhancement in mineralization.
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Journal: Chemosphere - Volume 179, July 2017, Pages 306-315