Thermodynamic and kinetic investigation of anaerobic bioprocesses on ANAMMOX under high organic conditions

Physical characteristics of SBR1 biomass in stage-V (A) and SBR2 biomass in Stage-III (B) and Stage-V (C). •ANAMMOX failed after 220 cycles’ operation with 100–800mg/L glucose in SBR.•Denitrification and sulfate-reduction activities were developed to 4 and 16 times.•Sulfate reduction emerged as an i...

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Bibliographic Details
Published in:Chemical engineering journal (Lausanne, Switzerland : 1996) Switzerland : 1996), 2013-08, Vol.230, p.149-157
Main Authors: Tang, Chong-Jian, Zheng, Ping, Chai, Li-Yuan, Min, Xiao-Bo
Format: Article
Language:English
Subjects:
ANAMMOX
Bacteria
Biomass
Chemical engineering
Denitrification
Deterioration
Kinetics
Organic matter
Reduction
SBR
Sludge
Sulfate reduction
Sulfates
Thermodynamics
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Summary:Physical characteristics of SBR1 biomass in stage-V (A) and SBR2 biomass in Stage-III (B) and Stage-V (C). •ANAMMOX failed after 220 cycles’ operation with 100–800mg/L glucose in SBR.•Denitrification and sulfate-reduction activities were developed to 4 and 16 times.•Sulfate reduction emerged as an important bioprocess for fade of ANAMMOX.•Thermodynamics and kinetics were evaluated for the substrate competitions. The long-term effects and mechanism of organic matter on ANAMMOX process was comparatively investigated by operating two SBRs. SBR1 was operated under inorganic conditions with an efficient and stable ANAMMOX performance. The autotrophic nitrogen removal performance of SBR2 gradually deteriorated and finally disappeared when influent COD concentration was progressively increased to 800mg/L during the 220 cycles’ operation. After dosing organic matter, the ANAMMOX activity of SBR2 biomass decreased to 1/4 of that of SBR1 sludge. Intensive denitrification and sulfate reduction were observed under the long-term exposure to organic matter. The denitrification and sulfate-reduction activities of SBR2 sludge finally developed to 4 and 16 times of the values of SBR1 biomass, respectively. Thermodynamic and kinetic analyses showed that both denitrification and sulfate reduction were enhanced under the high organic conditions. ANAMMOX bacteria could be eliminated from the SBR system due to preferential metabolization of nitrite by denitrification and, thus causing starvation of ANAMMOX bacteria.
ISSN:1385-8947
1873-3212
DOI:10.1016/j.cej.2013.06.047