Thermophilic bacteria combined with alkyl polyglucose pretreated mariculture solid wastes using as denitrification carbon source for marine recirculating aquaculture wastewater treatment

In marine recirculating aquaculture systems (RAS), efficient nitrogen removal is challenging due to the high NO3−-N concentration, low organic matters content, and high salinity. In this study, mariculture solid wastes (MSW) acidogenic liquid pretreated by thermophilic bacteria (TB) combined with al...

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Published inThe Science of the total environment Vol. 792; p. 148447
Main Authors Liu, Yuanjun, Guo, Liang, Gao, Pengtao, Yu, Dan, Yao, Zhiwen, Gao, Mengchun, Zhao, Yangguo, Jin, Chunji, She, Zonglian
Format Journal Article
LanguageEnglish
Published Elsevier B.V 20.10.2021
Subjects
Alkyl polyglucose
COD/NO3−-N ratio
Denitrification
Mariculture solid wastes
Recirculating aquaculture systems
Thermophilic bacteria
Thermophilic bacteria
Denitrification
Recirculating aquaculture systems
COD/NO3−-N ratio
Alkyl polyglucose
Mariculture solid wastes
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Abstract In marine recirculating aquaculture systems (RAS), efficient nitrogen removal is challenging due to the high NO3−-N concentration, low organic matters content, and high salinity. In this study, mariculture solid wastes (MSW) acidogenic liquid pretreated by thermophilic bacteria (TB) combined with alkyl polyglucose (APG) was first used as carbon source for denitrification to remove NO3−-N. TB + APG pretreatment could accelerate the hydrolysis of MSW, and the highest volatile fatty acids (VFAs) yield (40.3%) was obtained with TB + 0.2 g/g VSS APG pretreatment. MSW acidogenic liquid pretreated by TB + 0.2 g/g VSS APG was a reliable carbon source for denitrification, and the optimum COD/NO3−-N ratio (C/N) was 8 with no residue of NOx−-N. VFAs were more effectively utilized by denitrifiers than carbohydrate and protein. The high denitrification potential (PDN) and denitrification rate (VDN) indicated the higher denitrification ability at C/N of 8 using MSW acidogenic liquid as carbon source. The outcomes of this work could provide useful information for promoting technological innovation in marine RAS wastewater treatment. [Display omitted] •TB + APG could synergistically enhance the hydrolysis and acidification of MSW.•MSW acidogenic liquid was the reliable carbon source for denitrification.•The optimum C/N was 8 with no residual of NOx−-N.•VFAs was the optimal carbon source in MSW acidogenic liquid.•The obvious superiority of optimum C/N was obtained by kinetics analysis.
AbstractList In marine recirculating aquaculture systems (RAS), efficient nitrogen removal is challenging due to the high NO3−-N concentration, low organic matters content, and high salinity. In this study, mariculture solid wastes (MSW) acidogenic liquid pretreated by thermophilic bacteria (TB) combined with alkyl polyglucose (APG) was first used as carbon source for denitrification to remove NO3−-N. TB + APG pretreatment could accelerate the hydrolysis of MSW, and the highest volatile fatty acids (VFAs) yield (40.3%) was obtained with TB + 0.2 g/g VSS APG pretreatment. MSW acidogenic liquid pretreated by TB + 0.2 g/g VSS APG was a reliable carbon source for denitrification, and the optimum COD/NO3−-N ratio (C/N) was 8 with no residue of NOx−-N. VFAs were more effectively utilized by denitrifiers than carbohydrate and protein. The high denitrification potential (PDN) and denitrification rate (VDN) indicated the higher denitrification ability at C/N of 8 using MSW acidogenic liquid as carbon source. The outcomes of this work could provide useful information for promoting technological innovation in marine RAS wastewater treatment. [Display omitted] •TB + APG could synergistically enhance the hydrolysis and acidification of MSW.•MSW acidogenic liquid was the reliable carbon source for denitrification.•The optimum C/N was 8 with no residual of NOx−-N.•VFAs was the optimal carbon source in MSW acidogenic liquid.•The obvious superiority of optimum C/N was obtained by kinetics analysis.
ArticleNumber 148447
Author Liu, Yuanjun
Jin, Chunji
She, Zonglian
Zhao, Yangguo
Gao, Mengchun
Gao, Pengtao
Yu, Dan
Yao, Zhiwen
Guo, Liang
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Keywords Thermophilic bacteria
Denitrification
Recirculating aquaculture systems
COD/NO3−-N ratio
Alkyl polyglucose
Mariculture solid wastes
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Snippet In marine recirculating aquaculture systems (RAS), efficient nitrogen removal is challenging due to the high NO3−-N concentration, low organic matters content,...
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SubjectTerms Alkyl polyglucose
COD/NO3−-N ratio
Denitrification
Mariculture solid wastes
Recirculating aquaculture systems
Thermophilic bacteria
Title Thermophilic bacteria combined with alkyl polyglucose pretreated mariculture solid wastes using as denitrification carbon source for marine recirculating aquaculture wastewater treatment
URI https://dx.doi.org/10.1016/j.scitotenv.2021.148447
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