Enhancement of Profenofos Remediation Using Stimulated Bioaugmentation Technique

Q Chemistry Journal of Advanced Oxidation Technologies Pub Date : 2017-01-02 DOI:10.1515/JAOTS-2017-0025

S. Siripattanakul-Ratpukdi, A. Vangnai, Warayut Patichot

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引用次数: 4

Abstract

Abstract Profenofos, an organophosphorus pesticide, has been reported its contamination in groundwater. The current study emphasized on the use of integrated bioaugmentation and biostimulation techniques to enhance profenofos bioremediation. A profenofos-degrading consortium including Pseudomonas strains was chosen as a bioaugmented culture. For stimulated condition adjustment, sodium succinate as an additional organic carbon supplement (4-500 mg-carbon/L) was applied in batch experiment. Column experiment was carried out for investigating profenofos remediation with different infiltration rates and cell numbers of 25 to 100 cm/d and 105 and 1015 CFU/mL, respectively. The batch result showed that the experiment with sodium succinate supplement efficiently degraded profenofos of more than 80%. At profenofos concentrations of 20 to 120 mg/L, the profenofos degradation ranged from 85 to 91%. For the column experiment, profenofos removal was between 30 to more than 90%. The infiltration rates and microbial numbers significantly affected the profenofos degradation. Lower infiltration rates or higher cell number resulted in higher profenofos removal performance. Based on the result from this study, it indicated that the profenofos degradation by the bioaugmented consortium under stimulated condition is effective and potential for future remediation practice.

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利用受激生物强化技术加强对丙烯磷的修复

摘要有机磷农药丙烯磷在地下水中的污染已被报道。目前的研究重点是利用综合生物增强和生物刺激技术来加强丙诺威的生物修复。选择含假单胞菌菌株的丙烯磷降解联合体作为生物增强培养。在批量试验中，采用琥珀酸钠作为有机碳补充剂(4 ~ 500 mg-carbon/L)进行受激条件调节。在25 ~ 100 cm/d和105、1015 CFU/mL不同浸润速率和细胞数条件下，采用柱式实验研究了丙诺福斯的修复效果。批量试验结果表明，添加琥珀酸钠可有效降解80%以上的丙诺威。在浓度为20 ~ 120 mg/L的环境下，对异丙膦的降解率为85% ~ 91%。在柱式实验中，丙酚去除率在30% ~ 90%以上。入渗速率和微生物数量显著影响丙诺威的降解。较低的渗透速率或较高的细胞数导致较高的丙烯诺福斯去除性能。本研究结果表明，生物增强联合体在模拟条件下对丙诺威的降解是有效的，具有潜在的修复应用前景。

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来源期刊

Journal of Advanced Oxidation Technologies 化学-物理化学

CiteScore

0.88

自引率

0.00%

发文量

审稿时长

1 months

期刊介绍： The Journal of advanced oxidation technologies (AOTs) has been providing an international forum that accepts papers describing basic research and practical applications of these technologies. The Journal has been publishing articles in the form of critical reviews and research papers focused on the science and engineering of AOTs for water, air and soil treatment. Due to the enormous progress in the applications of various chemical and bio-oxidation and reduction processes, the scope of the Journal is now expanded to include submission in these areas so that high quality submission from industry would also be considered for publication. Specifically, the Journal is soliciting submission in the following areas (alphabetical order): -Advanced Oxidation Nanotechnologies -Bio-Oxidation and Reduction Processes -Catalytic Oxidation -Chemical Oxidation and Reduction Processes -Electrochemical Oxidation -Electrohydraulic Discharge, Cavitation & Sonolysis -Electron Beam & Gamma Irradiation -New Photocatalytic Materials and processes -Non-Thermal Plasma -Ozone-based AOTs -Photochemical Degradation Processes -Sub- and Supercritical Water Oxidation -TiO2 Photocatalytic Redox Processes -UV- and Solar Light-based AOTs -Water-Energy (and Food) Nexus of AOTs