Feasibility of reinforced post-endogenous denitrification coupling with synchronous nitritation, denitrification and phosphorus removal for high-nitrate sewage treatment using limited carbon source in municipal wastewater

Post-endogenous denitrification (PED) process, utilizing internal rather than external carbons, has been proposed for nitrogen removal from wastewaters. However, its potential nitrogen removal capacity has not been approached, especially when facing simultaneous phosphorus removal. Here, the nitroge...

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Bibliographic Details
Published in:Chemosphere (Oxford) 2021-04, Vol.269, p.128687, Article 128687
Main Authors: Gong, Xiuzhen, Yu, Deshuang, Wang, Xiaoxia, Yuan, Mengfei, Bi, Chunxue, Du, Yeqi, Zhao, Ji
Format: Article
Language:English
Subjects:
Bioreactors
Carbon
Carbon source
Denitrification
Feasibility Studies
High-nitrate sewage
Nitrates
Nitrification
Nitrogen
Phosphorus
Phosphorus removal
Post-endogenous denitrification (PED)
Sewage
Synchronous nitritation and denitrification (SNiD)
Waste Disposal, Fluid
Waste Water
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Summary:Post-endogenous denitrification (PED) process, utilizing internal rather than external carbons, has been proposed for nitrogen removal from wastewaters. However, its potential nitrogen removal capacity has not been approached, especially when facing simultaneous phosphorus removal. Here, the nitrogen removal ability of PED was further investigated by treating municipal and high-nitrate wastewaters in a novel process combined with synchronous nitritation, denitrification and phosphorus removal (SNiDPR). After optimization, the anoxic specific nitrite (and nitrate) reduction rate was increased from 0.41 to 1.13 mgN gVSS−1 h−1, accompanied with PED efficiency raising from 16.8% to 80.9%. It ensured that, by utilizing the limited organic carbons in municipal wastewater, deep-level nutrient removal could still be achieved (total nitrogen and phosphorus removal efficiencies were 93.1% and 99.9%, respectively). Nitrospira (0.1–0.4%) was outcompeted by Nitrosomonas (4.7–3.3%), which contributed to accumulation of nitrite in aerobic stage (99.6%) and dramatically reduced the carbons demand of following PED. Enriched Dechloromonas (8.5–5.6%) and Candidatus_Competibacter (9.1–11.3%) might play key roles in sufficient utilization of organic carbons in municipal wastewater anaerobically, and respectively facilitate aerobic phosphorus removal (100%) and anoxic PED (60.7% of overall nitrogen removal). [Display omitted] •The novel SNiDPR-PED was superior in treating municipal and high-nitrate sewages.•High TN and P removal (93.1% and 99.9%) was first approached without extra carbon.•Nitritation promoted PED to increase N removal with low aeration and carbon demand.•Coexisted Nitrosomonas, Dechloromonas, Candidatus_Competibacter ensured SNiDPR-PED.•SNiDPR-PED is promising to retreat effluents from main-and-side streams in WWTPs.
ISSN:0045-6535
1879-1298
DOI:10.1016/j.chemosphere.2020.128687