Bacterial community compositions of propylene oxide saponification wastewater treatment plants?
RSC Advances Pub Date: 2017-04-21 DOI: 10.1039/C6RA27808F
Abstract
The activated sludge process has been successfully used to treat propylene oxide (PO) saponification wastewater, which has the characteristics of high chlorine contents (22?000–26?000 mg L?1) and high COD (more than 2000 mg L?1). Microorganisms, especially bacteria, play an important role in PO saponification wastewater treatment processes. Analysis of the bacterial composition of the aeration tank and contact oxidation tank, the two main components of PO saponification wastewater treatment plants (SWWTP), revealed their significant community difference in municipal and coking wastewater treatment plants. Interestingly, β-Proteobacteria was almost absent in the PO SWWTP, which was usually abundant in various bio-treatment systems. In the aeration tank of PO SWWTP, the most abundant genera were Marinobacter, Mesorhizobium, Paracoccus, Devosia, Methylophaga and KSA1. In the contact oxidation tank of PO SWWTP, the most abundant genera were Thalassospira, Marinobacter, Owenweeksia, Novispirillum, Mesorhizobium, Sporotomaculum, Pseudidiomarina and KSA1. We also measured the total components and toxicity of PO saponification wastewater in order to establish correlations between bacterial stains, genes and their treatment capacity. The results indicated that most of the bacteria encoded the dehalogenase gene and played an important role in the dechlorinating process of chlorinated organics in the aeration tank. In contrast, most of the bacteria encode the alkJ gene in the contact oxidation tank, which was involved in the degradation of 2,4-dimethyl-2-pentanol or some dechlorinated intermediate products. This study would provide new insight into the microbial community compositions of PO SWWTPs.
Recommended Literature
- [1] An artificial photosynthesis system comprising a covalent triazine framework as an electron relay facilitator for photochemical carbon dioxide reduction? Siquan Zhang,Shengyao Wang,Liping Guo,Hao Chen,Bien Tan,Shangbin JinJ. Mater. Chem. C, 2020,8, 192-200 10.1039/C9TC05297F
- [2] An integrated process of CO2 capture and in situ hydrogenation to formate using a tunable ethoxyl-functionalized amidine and Rh/bisphosphine system? Yu-Nong Li,Liang-Nian He,Xian-Dong Lang,Xiao-Fang Liu,Shuai ZhangRSC Adv., 2014,4, 49995-50002 10.1039/C4RA08740B
- [3] An atom efficient route to N-aryl and N-alkyl pyrrolines by transition metal catalysis? Supaporn Sawadjoon,Joseph S. M. SamecOrg. Biomol. Chem., 2011,9, 2548-2554 10.1039/C0OB00383B
- [4] Alt-proteins: A promising future 10.1002/fsat.3701_10.x
- [5] An autonomous self-optimizing flow machine for the synthesis of pyridine–oxazoline (PyOX) ligands? Eric Wimmer,Daniel Cortés-Borda,Solène Brochard,Elvina Barré,Charlotte Truchet,Fran?ois-Xavier FelpinReact. Chem. Eng., 2019,4, 1608-1615 10.1039/C9RE00096H
- [6] An apparatus for testing water by measurement of its electrical conductivity Analyst, 1912,37, 538-543 10.1039/AN9123700538
- [7] Aluminium complexes with thio-phosphorus ligands: syntheses and characterisations of [Al2(CyPS3)2(CyPHS2)2] and [Al(S2PPh2)3]? Robert P. Davies,Maria A. Giménez,Laura Patel,Andrew J. P. WhiteDalton Trans., 2008, 5705-5707 10.1039/B813427H
- [8] An integrated chip for immunofluorescence and its application to analyze lysosomal storage disorders Jie Shen,Ying Zhou,Tu Lu,Junya Peng,Zhixiang Lin,Yuhong Pang,Li YuLab Chip, 2012,12, 317-324 10.1039/C1LC20845D
- [9] An alkynylboronatecycloaddition strategy to functionalised benzyne derivatives? James D. Kirkham,Patrick M. Delaney,George J. Ellames,Eleanor C. Row,Joseph P. A. HarrityChem. Commun., 2010,46, 5154-5156 10.1039/C0CC01345E
- [10] An investigation into the origin of variations in photovoltaic performance using D–D–π–A and D–A–π–A triphenylimidazole dyes with a copper electrolyte? Govind ReddyMol. Syst. Des. Eng., 2021,6, 779-789 10.1039/D1ME00073J
Journal Name:RSC Advances
research_products
-
CAS no.: 89640-58-4