Nitric oxide and nitrite removal by partial denitrifying hollow-fiber membrane biofilm reactor coupled with nitrous oxide generation as energy recovery

Nitric oxide and nitrite removal by partial denitrifying hollow-fiber membrane biofilm reactor coupled with nitrous oxide generation as energy recovery

Nitrogen oxide (NOx) emissions cause significant impacts on the environment and must therefore be controlled even more stringently. This requires the development of cost-effective removal strategies which simultaneously create value-added by-products or energy from the waste. This study aims to trea...

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Bibliographic Details
Published in:Environmental technology Vol. 43; no. 19; pp. 2934 - 2947
Main Authors: Yu, Khin Hnin, Can, Faruk, Ergenekon, Pınar
Format: Journal Article
Language:English
Published: England Taylor & Francis 24-08-2022
Taylor & Francis Ltd
Subjects:
Biofilms
Bioreactors
Carbon/nitrogen ratio
Denitrification
Dominant species
Emissions
Energy recovery
Hollow fiber membranes
Hollow-fibre membrane biofilm reactor
Load distribution
Loading rate
Nitric oxide
Nitrogen
Nitrogen oxides
Nitrous oxide
NO removal
O production
Oxidants
Oxidation
Oxidizing agents
partial denitrification
Photochemicals
Pseudomonas putida
Reactors
rRNA 16S
Sequence analysis
Hollow-fibre membrane biofilm reactor
energy recovery
partial denitrification
NO removal
N2O production
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Summary:Nitrogen oxide (NOx) emissions cause significant impacts on the environment and must therefore be controlled even more stringently. This requires the development of cost-effective removal strategies which simultaneously create value-added by-products or energy from the waste. This study aims to treat gaseous nitric oxide (NO) by hollow-fibre membrane biofilm reactor (HFMBfR) in the presence of nitrite ( ) and evaluate nitrous oxide (N 2 O) emissions formed as an intermediate product during the denitrification process. Accumulated N 2 O can be utilised in methane oxidation as an oxidant to produce energy. In the first stage of the study, the HFMBfR was operated by feeding only gaseous NO as the nitrogen source. During this period, the best performance was achieved with 92% NO removal efficiency (RE). In the second stage, both NO gas and were supplied to the system, and 91% NO and 99% reduction were achieved simultaneously with the maximum N 2 O generation of 386 ± 31 ppm. Lower influent carbon to nitrogen (C/N) ratios, such as 4.5 and 2.0, and higher −N loading rate of 158 mg N day −1 favoured N 2 O generation. An improved NO removal rate and N 2 O accumulation were seen with the increasing amount of in the medium. The 16S rDNA sequencing analysis revealed that Alicycliphilus denitrificans and Pseudomonas putida were the dominant species. The study shows that an HFMBfR can be successfully used to eliminate both and gaseous NO and simultaneously generate N 2 O by adjusting the system parameters such as C/N ratio, and loading.
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ISSN:0959-3330
1479-487X
DOI:10.1080/09593330.2021.1910348