Air non-thermal plasma, a green approach for the treatment of contaminated water: the case of sulfamethoxazole

Agata Giardina, G. Lofrano, G. Libralato, A. Siciliano, E. Marotta, C. Paradisi
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Abstract

Non-thermal plasma (NTP) is gaining increasing attention as a promising approach for advanced water treatment to degrade persistent organic pollutants. Aqueous solutions of sulfamethoxazole (4-amino-N-(5-methylisoxazol-3-yl)-benzensulfonamide, SMZ), an antibiotic largely employed for humans and animals and a widespread persistent pollutant of waters and wastewaters, were subjected to air NTP treatment in a dielectric barrier discharge (DBD) reactor. The effects of SMZ initial concentration and of the solution pH on SMZ decomposition kinetics and transformation products were investigated. Efficient degradation was achieved, resulting in the complete removal of SMZ (10 μM initial concentration) in less than 25 min treatments, in the exhaustive mineralization (a result never reported before in plasma treatments and seldom reached also with other advanced oxidation processes) of all organic carbon in 6 h and in an energy efficiency of 6.4 g/kWh at 50% conversion. By means of HPLC-UV/Vis and LC-ESI-MSn analyses, a number of organic transformation products was identified along the path to SMZ mineralization, all present always in very small amounts and in turn decomposed at short treatment times. The effect of the solution pH on the genesis and decay of transformation products was also investigated. Based on comparisons with literature data and on previous findings obtained with the DBD reactor used in this work, it is concluded that the major reactive species involved in the degradation of SMZ are the hydroxyl radical and ozone. Finally, toxicological analyses of water initially containing 0.5 mM SMZ and subjected to 4 h NTP treatment showed that the by-products are not toxic to Raphidocelis subcapitata and Daphnia magna, while residual toxicity was detected by Aliivibrio fischeri.
空气非热等离子体--处理受污染水的绿色方法:磺胺甲噁唑案例
非热等离子体(NTP)作为一种降解持久性有机污染物的先进水处理方法,正受到越来越多的关注。磺胺甲噁唑(4-氨基-N-(5-甲基异恶唑-3-基)-苯磺酰胺,SMZ)是一种主要用于人类和动物的抗生素,也是一种广泛存在于水体和废水中的持久性污染物。研究了 SMZ 初始浓度和溶液 pH 值对 SMZ 分解动力学和转化产物的影响。在不到 25 分钟的处理过程中,SMZ(初始浓度为 10 μM)被完全去除,所有有机碳在 6 小时内被完全矿化(这是等离子体处理过程中从未报道过的结果,其他高级氧化过程也很少达到这一结果),50% 转化时的能效为 6.4 g/kWh。通过 HPLC-UV/Vis 和 LC-ESI-MSn 分析,在 SMZ 矿化过程中发现了许多有机转化产物,它们的含量都很低,并且在很短的处理时间内就会被分解。此外,还研究了溶液 pH 值对转化产物的生成和分解的影响。根据与文献数据的比较以及之前使用 DBD 反应器得出的结论,参与 SMZ 降解的主要反应物是羟基自由基和臭氧。最后,对最初含有 0.5 毫摩尔 SMZ 并经过 4 小时 NTP 处理的水进行的毒理学分析表明,副产品对 Raphidocelis subcapitata 和 Daphnia magna 没有毒性,而对 Aliivibrio fischeri 有残留毒性。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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