Impact of Advanced Oxidation Processes on the Composition and Biodegradability of Soluble Organic Nutrients in Wastewater Effluents

A. Gu, N. Tooker
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Advanced oxidation processes (AOPs) have been shown to be capable of reducing the concentrations of soluble organic nutrients and converting specific nutrient-containing organic compounds into simpler or more biodegradable forms. The overall objective of this study was to investigate the impact of AOP treatments on the speciation and composition of soluble nutrients and consequently their biodegradability in wastewater effluents. Secondary or tertiary effluents from three selected wastewater treatment plants were collected. Each effluent was treated with three different AOPs, including low-pressure ultraviolet (UV) irradiation, hydrogen peroxide (H2O2), and a combination of UV and H2O2. Both untreated and AOP-treated effluents were subjected to a comprehensive analysis for wastewater characterization, nitrogen speciation analysis, phosphorus speciation analysis, and soluble organic nitrogen (SON) biodegradability assays. 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引用次数: 1

Abstract

The characteristics and bioavailability of wastewater derived “refractory” organic nutrients and their susceptibility to removal has drawn significant attention from both regulatory agencies and wastewater utilities. As suggested by recent studies, the bioavailability of effluent organic nutrients to algae is relatively high. This implies that discharge of effluent organic nutrients from water resource recovery facilities (WRRFs) may contribute to eutrophication potential. Therefore, investigation into alternative technologies for organic nutrients transformation and reduction, and the mechanisms involved in those processes, is warranted with the ultimate goal of improved eutrophication control. Advanced oxidation processes (AOPs) have been shown to be capable of reducing the concentrations of soluble organic nutrients and converting specific nutrient-containing organic compounds into simpler or more biodegradable forms. The overall objective of this study was to investigate the impact of AOP treatments on the speciation and composition of soluble nutrients and consequently their biodegradability in wastewater effluents. Secondary or tertiary effluents from three selected wastewater treatment plants were collected. Each effluent was treated with three different AOPs, including low-pressure ultraviolet (UV) irradiation, hydrogen peroxide (H2O2), and a combination of UV and H2O2. Both untreated and AOP-treated effluents were subjected to a comprehensive analysis for wastewater characterization, nitrogen speciation analysis, phosphorus speciation analysis, and soluble organic nitrogen (SON) biodegradability assays. The AOP processes at the conditions applied did not lead to significant changes in the SON concentrations for the wastewater effluents examined. However, fingerprinting and quantification of the dissolved organic matter (DOM) in untreated and AOP treated samples using fluorescence spectroscopy combined with parallel factor analysis revealed changes in DOM pool composition with various AOP treatments. This suggests that there may also be changes in organic nutrients composition. Based on biodegradability assessments, AOP treatments likely changed the composition and biodegradability of the SON compounds in the effluents. The impact of AOP treatments on effluent biodegradable SON (BSON) varied depending on the effluent and the AOP treatment. The BSON concentration increased by 0.02-0.2 mg/L (4-47%) after AOP treatment in one effluent, while the concentration decreased by 0.12-0.14 mg/L (60-69%) in another sample. For the secondary effluent sample, release of ammonia (0.04-0.1 mg/L) was observed during 15-day BSON incubation period for those samples treated with H2O2 or UV/H2O2, suggesting that the AOP treatments might lead to oxidation of colloidal organic matter in the filtered effluent. Comparison of the results among the three different AOPs indicated that the combined UV/H2O2 treatment was more effective at oxidizing some of the organic or organically bound nutrients. The impact of AOP treatment on effluent soluble organic phosphorus (SOP) composition varied depending on the effluents. For two WRRFs, AOP treatment at the dose conditions applied led to a decrease in the SOP level and seemed to convert it into SAHP, indicating a possible increase in effluent soluble phosphorus bioavailability. Comparison of the results among the three different AOPs indicated that the combined UV/H2O2 treatment was more effective at oxidizing some of the organic or organically bound P compounds into a more readily removable form than either UV or H2O2 alone. With the limited number of effluents evaluated and under the conditions applied in this study, AOP treatments did not seem to significantly increase the biodegradability of SON. Therefore the proposed SON removal via AOP followed by biological treatment does not seem to be promising. Further investigation with more effluents is needed. Economic or life cycle assessment (LCA) analysis should be performed to assess the overall benefits compared to the cost of implementing high-cost advanced treatment processes such as AOP. Other nutrient control measures and regulations should also be considered. This title belongs to WERF Research Report Series ISBN: 9781780408040 (eBook)
深度氧化工艺对废水中可溶性有机营养物组成和可降解性的影响
废水衍生的“难降解”有机营养物的特性和生物利用度及其对去除的敏感性引起了监管机构和废水公用事业公司的极大关注。近年来的研究表明,出水有机营养物对藻类的生物利用度较高。这意味着,从水资源回收设施(WRRFs)排放出水有机营养物可能有助于富营养化潜力。因此,研究有机养分转化和减少的替代技术以及这些过程中涉及的机制是有必要的,最终目标是改善富营养化控制。高级氧化过程(AOPs)已被证明能够降低可溶性有机营养物的浓度,并将特定含营养物的有机化合物转化为更简单或更可生物降解的形式。本研究的总体目标是研究AOP处理对废水中可溶性营养物质的形态和组成的影响,从而影响它们的生物降解性。收集了三个选定的污水处理厂的二级或三级污水。每个废水用三种不同的AOPs处理,包括低压紫外线(UV)照射、过氧化氢(H2O2)以及紫外线和H2O2的组合。对未经处理和aop处理的废水进行了综合分析,包括废水表征、氮形态分析、磷形态分析和可溶性有机氮(SON)生物降解性分析。在所应用的条件下,AOP过程没有导致所检查的废水流出物的SON浓度发生显着变化。然而,利用荧光光谱结合平行因子分析对未处理和AOP处理样品的溶解有机质(DOM)进行指纹识别和定量分析,揭示了不同AOP处理下DOM池组成的变化。这表明有机营养成分也可能发生变化。基于生物可降解性评估,AOP处理可能改变了出水中SON化合物的组成和生物可降解性。AOP处理对出水生物降解SON (BSON)的影响因出水和AOP处理而异。一种样品经AOP处理后BSON浓度提高了0.02 ~ 0.2 mg/L(4-47%),另一种样品的BSON浓度降低了0.12 ~ 0.14 mg/L(60-69%)。对于二级出水样品,在H2O2或UV/H2O2处理15 d的BSON孵育期间,观察到氨的释放(0.04 ~ 0.1 mg/L),表明AOP处理可能导致过滤出水中的胶体有机物氧化。三种不同AOPs处理的结果比较表明,UV/H2O2联合处理对氧化部分有机或有机结合的营养物更有效。AOP处理对出水可溶性有机磷(SOP)组成的影响随出水的不同而不同。对于两个wrrf,在所施加的剂量条件下,AOP处理导致SOP水平下降,并似乎将其转化为SAHP,表明出水可溶性磷的生物利用度可能增加。结果表明,与单独使用UV或H2O2相比,UV/H2O2联合处理能更有效地将一些有机或有机结合的P化合物氧化成更易于去除的形式。由于评估的废水数量有限,在本研究应用的条件下,AOP处理似乎没有显著提高SON的生物降解性。因此,建议通过AOP去除SON,然后进行生物处理似乎不太有希望。需要对更多的污水进行进一步的研究。应该执行经济或生命周期评估(LCA)分析,以评估与实施高成本高级处理过程(如AOP)的成本相比的总体效益。还应考虑其他营养控制措施和规定。本文归属于WERF研究报告丛书ISBN: 9781780408040(电子书)
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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