Effects of high ammonia loading and in-situ short-cut nitrification in low carbon‑nitrogen ratio wastewater treatment by biocathode microbial electrochemical system

Effects of high ammonia loading and in-situ short-cut nitrification in low carbon‑nitrogen ratio wastewater treatment by biocathode microbial electrochemical system

The microbial electrochemical system (MES) has great advantages in wastewater treatment for rapid chemical oxygen demand (COD) removal and low sludge yield rate. Herein, biocathode MES was proposed to remove COD from high-ammonia wastewater with low carbon‑nitrogen ratio and regulate the nitrogen fo...

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Bibliographic Details
Published in:The Science of the total environment Vol. 755; no. Pt 2; p. 142641
Main Authors: Niu, Jiaojiao, Feng, Yujie, Wang, Naiyu, Liu, Shujuan, Liang, Yuhai, Liu, Jia, He, Weihua
Format: Journal Article
Language:English
Published: Netherlands Elsevier B.V 10-02-2021
Subjects:
Ammonia - analysis
Ammonia nitrogen loading
Bacteria community
Biocathode performance
Bioreactors
Carbon
Denitrification
Microbial electrochemical system
Nitrification
Nitrogen
Oxidation-Reduction
Short-cut nitrification
Waste Water
Water Purification
Biocathode performance
Bacteria community
Microbial electrochemical system
Ammonia nitrogen loading
Short-cut nitrification
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Summary:The microbial electrochemical system (MES) has great advantages in wastewater treatment for rapid chemical oxygen demand (COD) removal and low sludge yield rate. Herein, biocathode MES was proposed to remove COD from high-ammonia wastewater with low carbon‑nitrogen ratio and regulate the nitrogen forms in effluent for ANAMMOX process. The biocathode was more sensitive to ammonia nitrogen (NH4+-N) than anode and determined the power generation of MES. With COD of 500–550 mg L−1 in influent, increasing NH4+-N from 50 to 150 mg L−1 improved maximum power output (Pmax) from 3.0 ± 0.2 to 3.4 ± 0.1 W m−3, which was then reduced with further increase of NH4+-N from 300 to 600 mg L−1. However, for the cathodic reductive current, the negative effects of ammonia only revealed with NH4+-N ≥ 450 mg L−1. The cathodic equilibrium potential drop determined the power degradation, because the increased reductive compounds (NH4+ and COD) in catholyte. The high NH4+-N reduced the abundance of denitrifiers, exoelectrogens and organic-degrading bacteria on electrodes, while that of nitrogen-fixing bacteria increased. External alkalinity addition achieved in-situ short-cut nitrification and nitrite accumulation. With comparable NH4+ and NO2−, limited NO3− and low COD, the biocathode MES effluent was then suitable for subsequence ANAMMOX process. [Display omitted] •The biocathode biofilm was more sensitive to ammonia nitrogen (NH4+-N) than anode.•The NH4+-N of 450 mg L−1 was identified as the critical stable point of biocathode.•The cathodic equilibrium potential drop determined the system power degradation.•The high NH4+-N reduced the abundance of key functional bacteria on electrodes.•External alkalinity addition achieved in-situ short cut nitrification in cathode.
ISSN:0048-9697
1879-1026
DOI:10.1016/j.scitotenv.2020.142641