Microbiological characterization and specific methanogenic activity of anaerobe sludges used in urban solid waste treatment

This study presents the microbiological characterization of the anaerobic sludge used in a two-stage anaerobic reactor for the treatment of organic fraction of urban solid waste (OFUSW). This treatment is one alternative for reducing solid waste in landfills at the same time producing a biogas (CH 4...

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Bibliographic Details
Published in:Waste management (Elmsford) 2009-02, Vol.29 (2), p.704-711
Main Authors: Lozano, Claudia Johanna Sandoval, Mendoza, Marisol Vergara, de Arango, Mariela Carreño, Monroy, Edgar Fernando Castillo
Format: Article
Language:English
Subjects:
09 BIOMASS FUELS
Anaerobiosis
Applied sciences
Bacteria, Anaerobic - metabolism
BIOLOGICAL PATHWAYS
Bioreactors
CARBON DIOXIDE
Cities
ETHANOL
Exact sciences and technology
General purification processes
General treatment and storage processes
MANURES
METHANE
Methane - chemistry
Methane - metabolism
METHANOGENIC BACTERIA
Other wastes and particular components of wastes
Pollution
Refuse Disposal - methods
SANITARY LANDFILLS
Sewage - microbiology
SOLID WASTES
Urban and domestic wastes
WASTE WATER
Wastes
Wastewaters
Water treatment and pollution
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Summary:This study presents the microbiological characterization of the anaerobic sludge used in a two-stage anaerobic reactor for the treatment of organic fraction of urban solid waste (OFUSW). This treatment is one alternative for reducing solid waste in landfills at the same time producing a biogas (CH 4 and CO 2) and an effluent that can be used as biofertilizer. The system was inoculated with sludge from a wastewater treatment plant (WWTP) (Río Frío Plant in Bucaramanga-Colombia) and a methanogenic anaerobic digester for the treatment of pig manure (Mesa de los Santos in Santander). Bacterial populations were evaluated by counting groups related to oxygen sensitivity, while metabolic groups were determined by most probable number (MPN) technique. Specific methanogenic activity (SMA) for acetate, formate, methanol and ethanol substrates was also determined. In the acidogenic reactor (R1), volatile fatty acids (VFA) reached values of 25,000 mg L −1 and a concentration of CO 2 of 90%. In this reactor, the fermentative population was predominant (10 5–10 6 MPN mL −1). The acetogenic population was (10 5 MPN mL −1) and the sulphate-reducing population was (10 4–10 5 MPN mL −1). In the methanogenic reactor (R2), levels of CH 4 (70%) were higher than CO 2 (25%), whereas the VFA values were lower than 4000 mg L −1. Substrate competition between sulphate-reducing (10 4–10 5 MPN mL −1) and methanogenic bacteria (10 5 MPN mL −1) was not detected. From the SMA results obtained, acetoclastic (2.39 g COD-CH 4 g −1 VSS −1 day −1) and hydrogenophilic (0.94 g COD-CH 4 g −1 VSS −1 day −1) transformations as possible metabolic pathways used by methanogenic bacteria is suggested from the SMA results obtained. Methanotrix sp., Methanosarcina sp., Methanoccocus sp. and Methanobacterium sp. were identified.
ISSN:0956-053X
1879-2456
DOI:10.1016/j.wasman.2008.06.021