Electron buffer formation through coupling thiosulfate-dependent denitratation with anammox in a single-stage sequencing batch reactor

[Display omitted] •The thiosulfate-dependent denitratation/anammox process was developed in ASBR.•The intermediates of thiosulfate oxidation can serve as an electron buffer.•The NO2− and NO produced by SOB were important substrates for anammox.•The isotope tracing method was used to reveal the pathw...

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Bibliographic Details
Published in:Bioresource technology 2020-09, Vol.312, p.123560-123560, Article 123560
Main Authors: Yang, Yan, Lu, Hui, Shao, Zhiyu, Liu, Shiyi, Zhang, Yuxin, Jiang, Debin, Gu, Li, He, Qiang, Chai, Hongxiang
Format: Article
Language:English
Subjects:
Anammox
Electron buffer
Isotope labeling
Removal pathway
Thiosulfate-dependent denitratation
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Summary:[Display omitted] •The thiosulfate-dependent denitratation/anammox process was developed in ASBR.•The intermediates of thiosulfate oxidation can serve as an electron buffer.•The NO2− and NO produced by SOB were important substrates for anammox.•The isotope tracing method was used to reveal the pathways of N transformation.•A 3-step reaction model was proposed to describe the pathways. The combination of thiosulfate-dependent denitratation and anammox in a single-stage reactor provides a feasible way to improve total nitrogen removal. The molar ratios of NH4+/NO3− and S2O32−/NO3− were confirmed to be two key factors affecting the reactor performance. The optimal total nitrogen removal efficiency of 99.4% was achieved at NH4+/NO3− of 0.75 and S2O32−/NO3− of 0.85. The multiple thiosulfate oxidation pathways contribute to electron buffers generated in the system. A novel isotope labeling method using 15N was applied to reveal N transformation pathways and a 3-step model was proposed. The nitrate was first converted to nitrite or nitric oxide (NO) by sulfur-oxidizing bacteria. In the second step, both nitrite and NO were utilized by anammox bacteria. Finally, the nitrate generated from anammox could be removed using sulfur deposits as electron donors. The findings provide a potential solution for mainstream nitrogen removal.
ISSN:0960-8524
1873-2976
DOI:10.1016/j.biortech.2020.123560