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Nitrification and microbiological evolution during aerobic treatment of municipal solid wastes

► Nitrogen dynamic was studied during aerobic treatment of fine organic fraction of municipal solid wastes. ► Evolution of different groups of microorganisms was investigated. ► Nitrification occurred only during the maturation stage. ► Ammonia-oxidizing bacteria were responsible for ammonia oxidati...

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Published in:Bioresource technology 2012-04, Vol.110, p.144-152
Main Authors: Zeng, Yang, De Guardia, Amaury, Ziebal, Christine, De Macedo, Flávia Junqueira, Dabert, Patrick
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Language:English
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description ► Nitrogen dynamic was studied during aerobic treatment of fine organic fraction of municipal solid wastes. ► Evolution of different groups of microorganisms was investigated. ► Nitrification occurred only during the maturation stage. ► Ammonia-oxidizing bacteria were responsible for ammonia oxidation during treatment. Nitrification is a key step in the nitrogen cycle in various ecosystems. In this study, the nitrogen dynamic and the evolution of groups of microorganisms were studied during aerobic treatment of fine organic fraction of municipal solid wastes. Mineralization of organic nitrogen exhibited two phases and resulted in two ammonia emissions peaks. The nitrogen balance indicated the onset of nitrification only during the maturation stage, which was confirmed by the accumulations of both nitrite and nitrate and the nitrous oxide emissions in this period. A significant development of ammonia-oxidizing bacteria correlated to the onset of nitrification. On the contrary, ammonia-oxidizing archaea were less abundant and declined through treatment. Identification of these ammonia oxidizers indicates that the Nitrosomonas europaea/eutropha-like ammonia oxidizing bacteria were responsible for ammonia oxidation instead of other groups of ammonia oxidizers during aerobic treatment of fine organic fraction of municipal solid wastes.
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Nitrification is a key step in the nitrogen cycle in various ecosystems. In this study, the nitrogen dynamic and the evolution of groups of microorganisms were studied during aerobic treatment of fine organic fraction of municipal solid wastes. Mineralization of organic nitrogen exhibited two phases and resulted in two ammonia emissions peaks. The nitrogen balance indicated the onset of nitrification only during the maturation stage, which was confirmed by the accumulations of both nitrite and nitrate and the nitrous oxide emissions in this period. A significant development of ammonia-oxidizing bacteria correlated to the onset of nitrification. On the contrary, ammonia-oxidizing archaea were less abundant and declined through treatment. 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Nitrification is a key step in the nitrogen cycle in various ecosystems. In this study, the nitrogen dynamic and the evolution of groups of microorganisms were studied during aerobic treatment of fine organic fraction of municipal solid wastes. Mineralization of organic nitrogen exhibited two phases and resulted in two ammonia emissions peaks. The nitrogen balance indicated the onset of nitrification only during the maturation stage, which was confirmed by the accumulations of both nitrite and nitrate and the nitrous oxide emissions in this period. A significant development of ammonia-oxidizing bacteria correlated to the onset of nitrification. On the contrary, ammonia-oxidizing archaea were less abundant and declined through treatment. 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ispartof Bioresource technology, 2012-04, Vol.110, p.144-152
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1873-2976
language eng
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source ScienceDirect Journals
subjects Aerobic treatment
Aerobiosis
ammonia
Ammonia - metabolism
Ammonia emissions
Archaea
bacteria
Bacteria - genetics
Bacteria - metabolism
biogeochemical cycles
ecosystems
emissions
Environmental Sciences
evolution
mineralization
municipal solid waste
Municipal solid wastes
nitrates
Nitrification
nitrites
Nitrogen
nitrogen balance
Nitrosomonas europaea
nitrous oxide
oxidation
Oxidation-Reduction
Real-Time Polymerase Chain Reaction
Refuse Disposal
RNA, Ribosomal, 16S - genetics
title Nitrification and microbiological evolution during aerobic treatment of municipal solid wastes
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