Nitrate and nitrite reduction activity of activated sludge microcosm in a highly alkaline environment with solid cementitious material

Denitrification is a major biological process contributing to nitrate and nitrite reduction. However, this process remains poorly understood at alkaline pH although such conditions can be encountered in natural (e.g. soda lakes) or industrial environments (e.g. geological waste repositories with cem...

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Bibliographic Details
Published in:International biodeterioration & biodegradation 2020-07, Vol.151, p.104971, Article 104971
Main Authors: Durban, Nadège, Sonois-Mazars, Vanessa, Albina, Pierre, Bertron, Alexandra, Albrecht, Achim, Robinet, Jean-Charles, Erable, Benjamin
Format: Article
Language:English
Subjects:
Activated sludge
Batch reactors
Biofilm
Biofilms
Biological activity
Bioreactors
Calcite
Cement
Cement paste
Cementitious environment
Civil Engineering
Denitrification
Denitrification rate
Deoxyribonucleic acid
DNA
Engineering Sciences
Labeling
Lakes
Leachates
Metabolism
Microorganisms
Nitrate reduction
Nitrates
Nitrites
pH effects
Physics
Reactors
Reduction
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Summary:Denitrification is a major biological process contributing to nitrate and nitrite reduction. However, this process remains poorly understood at alkaline pH although such conditions can be encountered in natural (e.g. soda lakes) or industrial environments (e.g. geological waste repositories with cementitious materials). To investigate the nitrate reduction (NR) rate for pH > 9.5 in a cementitious environment, several batch reactors were implemented, with cement leachate or with hardened cement paste (HCP). In the experiments carried out with cement leachate, NR dropped from 0.72 mM/h at pH 9.5 to 0.17 mM/h at pH > 11, while the concentration of nitrite increased. The NR was inhibited at pH close to 12, as was the nitrite reduction at pH above 11. In the reactor containing HCP, the NR rate was 0.75 mM/h at pH close to 10. Calcite precipitated on the HCP surface. Epifluorescence microscopy observations coupled with DNA labelling suggested the presence of microorganisms attached to the HCP surface. This was confirmed by biological growth coupled with NR activity after the transfer of the HCP into a new medium, considered to be sterile. The bacterial community analysis showed that the highly selective culture conditions led to the selection of two species: Halomonas sp. and a species known for its versatile metabolism and ability to form biofilms, i.e. Thauera sp. [Display omitted] •Alkalophilic denitrification in a cementitious environment.•Nitrate reduction rate decreased as pH increased – pH range from 9 to 12.•Nitrite reduction and microbial growth were only at pH 
ISSN:0964-8305
1879-0208
DOI:10.1016/j.ibiod.2020.104971