Abstract
Partial (PN) combined with anaerobic oxidation process has been recognized as a promising technology for the���� removal of nitrogenous contaminants from . This research aimed to investigate ������the potential of external for enhancing the PN process in short and long term laboratory-scale experiments. Different strength magnetic fields (0, 5, 10, 15, 20 and 25 mT) were evaluated in short-term batch tests and 5 mT magnetic fi�����eld was found to have better ability to increase the activities of aerobic ammonium oxidizing bacteria (AOB) of PN consortium. �������; of magnetic field on PN consortium was studied with 5 mT magnetic field. The results demonstrated that the positive effect of magnetic field on PN process could also be testified at all of the four stages. Furthermore, a d����ecrease of bacterial diversity was noted with the increase of magnetic field strength. of Nitrosomonadaceae decreased sign��������ificantly (p < 0.01) from 13.9% i�����n RCK to 12.9% in R5mT and 5.5% in R25mT. Functional genes forecast based on KEGG database indicated that the expressions of functional genes related to signal transduction and cell ������������in 5 mT environment were higher expressed compared with no magnetic field addition and high magnetic field addition. The existence of 5 mT magnetic field didn't increase the abundance of AOB but increased the activity of AOB by increasing the rate of free into the interior of microbial cells. Addition of magnetic field couldn'����t change the final state of PN process according to the hypothesis proposed in this article. These findings indicated that the weak magnetic field was useful and reliable for the fast start-up of PN process since it was proved as a simple and convenient approach to enhance AOB activity.
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