利用铂阳极电-芬顿法研究水中氧氟沙星的氧化降解和矿化动力学及氧化产物,并优化生物降解过程

IF 0.5 4区 化学 Q4 CHEMISTRY, ANALYTICAL
Rabab A. Hakami, Afnan A. Hakami, Muna Shueai Yahya
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引用次数: 0

摘要

在 100 至 500 mA 的恒定电流和碳毡阴极条件下,采用电-芬顿(EF)工艺研究了抗生素氧氟沙星(OFX)的氧化降解。研究了氧化降解的动力学和矿化效率与应用电流和催化剂(Fe2+)浓度的关系。采用竞争动力学方法确定了羟自由基氧化 OFX 的绝对速率常数为 3.04 ± 0.19 × 109 M-1s-1。为了在相关操作条件下有效降解 OFX,催化剂(Fe2+)浓度为 0.10 mM 时的理想电流值为 400 mA。本研究表明,经过 6 小时的电解,碳毡(CF)、碳石墨(CG)和不锈钢(SS)等几种阴极都对有机污染物 OFX 的电化学氧化产生了影响。矿化度达到了很高的水平(97%)。此外,还监测了 F-、\({\{NH}}_{\{4}}}^{\{ + }}}\) 和\({\{NO}}_{\{3}}}^{ - }\) 离子的发展,并讨论了它们在释放到介质中过程中的演变。使用 LC-MS/MS(液相色谱-质谱法)和 HPLC(高效液相色谱法)分析确定了几种中间产物。根据这些产物的特性,提出了矿化过程的可行路线。最后,对生物降解性进行了研究,结果表明,通过 EF 处理使 OFX 矿化,5 天内生物需氧量与化学需氧量 BOD5/COD 的比率如下,因此可以评估电-芬顿和生物处理相结合的可能性。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Study of Oxidative Degradation and Mineralization Kinetics and Oxidation Products of Ofloxacin in Water via Electro-Fenton Method with Pt Anode, and Biodegradation Optimization

Study of Oxidative Degradation and Mineralization Kinetics and Oxidation Products of Ofloxacin in Water via Electro-Fenton Method with Pt Anode, and Biodegradation Optimization

Study of Oxidative Degradation and Mineralization Kinetics and Oxidation Products of Ofloxacin in Water via Electro-Fenton Method with Pt Anode, and Biodegradation Optimization

The oxidative degradation of an antibiotic, Ofloxacin (OFX), has been investigated using the electro-Fenton (EF) process with a constant current between 100 and 500 mA and a carbon-felt cathode. The kinetics of oxidative degradation and the efficiency of mineralization were examined about the applied current and catalyst (Fe2+) concentration. The absolute rate constant for the oxidation of OFX by hydroxyl radical was determined using the competition kinetic approach as 3.04 ± 0.19 × 109 M–1s–1. For efficient degradation of OFX at the relevant operating conditions, the ideal current value is 400 mA at a concentration of the catalyst (Fe2+) at 0.10 mM. After 6 h of electrolysis, in the present study, it is demonstrated that several cathodes, including carbon felt (CF), carbon-graphite (CG) and stainless steel (SS), had an impact on the electrochemical oxidation of the organic contaminant, OFX. A high level of mineralization (>97%) was attained. The development of F, \({\text{NH}}_{{\text{4}}}^{{\text{ + }}}\) and \({\text{NO}}_{{\text{3}}}^{ - }\) ions was also monitored and their evolution during their release into the medium was discussed. Several intermediate products were identified using LC-MS/MS (liquid chromatography-mass spectrometry) and HPLC (High-performance liquid chromatography) analyses. Based on the identity of these products, a feasible route for the mineralization process is proposed. Finally, biodegradability was studied and the results indicated the following ratio of biological oxygen demand within 5 days to chemical oxygen demand BOD5/COD through OFX mineralization by EF treatment for the possibility of evaluating the combination of electro-Fenton and biological treatment.

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来源期刊
Journal of Water Chemistry and Technology
Journal of Water Chemistry and Technology CHEMISTRY, APPLIED-CHEMISTRY, ANALYTICAL
自引率
0.00%
发文量
51
审稿时长
>12 weeks
期刊介绍: Journal of Water Chemistry and Technology focuses on water and wastewater treatment, water pollution monitoring, water purification, and similar topics. The journal publishes original scientific theoretical and experimental articles in the following sections: new developments in the science of water; theoretical principles of water treatment and technology; physical chemistry of water treatment processes; analytical water chemistry; analysis of natural and waste waters; water treatment technology and demineralization of water; biological methods of water treatment; and also solicited critical reviews summarizing the latest findings. The journal welcomes manuscripts from all countries in the English or Ukrainian language. All manuscripts are peer-reviewed.
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