Biotreatability Improvement of Antibiotic-Contaminated Waters: High Efficiency of Direct Ozonation in Comparison to Hydroxyl Radical Oxidation.

IF 1.2 4区化学 Q3 CHEMISTRY, MULTIDISCIPLINARY

Acta Chimica Slovenica Pub Date : 2023-03-20 DOI:10.17344/acsi.2022.7793

Igor Bosevski, Andreja Žgajnar Gotvajn

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Abstract

Efficiencies of direct ozonation and hydroxyl radical oxidation by Fenton process were compared, aiming to improve biotreatability of antibiotics contaminated water (tiamulin, amoxicillin and levofloxacin). Biodegradability, COD (chemical oxygen demand) and TOC (total organic carbon) were measured before and after applying oxidative process. It was confirmed that significantly smaller molar dose of ozone (1.1 mgO3 / mgatb) against the hydrogen peroxide (17 mgH2O2 / mgatb), deliver comparable improvements of biodegradability; Tiamulin biodegraded up to 60 %, levofloxacin close to 100 %. Ozonation removed more TOC (10%, 29% and 8% for tiamulin, levofloxacin and amoxicillin, respectively) than Fenton process. This is confirming mineralization of antibiotics, not only biodegradable intermediates formation. In terms of costs, ozonation is more feasible in oxidizing complex antibiotics in water, as it targets functional groups which carry antimicrobial properties. This brings not only improved biodegradability needed for a conventional biological treatment plant, but also reduces long-term impacts of the antibiotics in the environment.

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提高抗生素污染水的生物处理性:与羟基自由基氧化法相比，直接臭氧氧化法效率更高。

比较了Fenton法直接臭氧氧化和羟基自由基氧化的效率，以提高抗生素污染水(tiamulin、阿莫西林和左氧氟沙星)的生物可处理性。测定氧化前后的生物降解性、COD(化学需氧量)和TOC(总有机碳)。结果表明，相对于过氧化氢(17 mgH2O2 / mgath)，更小摩尔剂量的臭氧(1.1 mgO3 / mgath)可显著提高生物降解性;天慕林生物降解率达60%，左氧氟沙星接近100%。臭氧氧化法比Fenton法对TOC的去除率分别为10%、29%和8% (tiamulin、左氧氟沙星和阿莫西林)。这证实了抗生素矿化，而不仅仅是生物可降解中间体的形成。就成本而言，臭氧氧化在水中氧化复合抗生素更可行，因为它针对的是携带抗菌特性的官能团。这不仅提高了传统生物处理厂所需的生物降解性，而且减少了抗生素对环境的长期影响。

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来源期刊

Acta Chimica Slovenica 化学-化学综合

CiteScore

2.50

自引率

25.00%

发文量

审稿时长

1.0 months

期刊介绍： Is an international, peer-reviewed and Open Access journal. It provides a forum for the publication of original scientific research in all fields of chemistry and closely related areas. Reviews, feature, scientific and technical articles, and short communications are welcome.