Spatial and temporal variations of greenhouse gas emissions from a waste stabilization pond: Effects of sludge distribution and accumulation

•WSPs were strong sources of CO2 and CH4 and weak sinks of N2O•Spatial variation of GHG emission strongly depends on sludge distribution•Diel variation was found in CO2 emissions but not in CH4 and N2O emissions•CO2 and N2O dissolved concentrations can be used as a reference of their emissions•Sludg...

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Bibliographic Details
Published in:Water research (Oxford) 2021-04, Vol.193, p.116858, Article 116858
Main Authors: Ho, Long, Jerves-Cobo, Ruben, Morales, Oscar, Larriva, Josue, Arevalo-Durazno, Maria, Barthel, Matti, Six, Johan, Bode, Samuel, Boeckx, Pascal, Goethals, Peter
Format: Article
Language:English
Subjects:
Carbon dioxide
Carbon Dioxide - analysis
Ecuador
Environmental Monitoring
Greenhouse Effect
Greenhouse gas
Greenhouse Gases - analysis
Methane
Methane - analysis
Nitrous oxide
Nitrous Oxide - analysis
Ponds
Sewage
Sludge
Spatiotemporal variation
Stabilization pond
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Summary:•WSPs were strong sources of CO2 and CH4 and weak sinks of N2O•Spatial variation of GHG emission strongly depends on sludge distribution•Diel variation was found in CO2 emissions but not in CH4 and N2O emissions•CO2 and N2O dissolved concentrations can be used as a reference of their emissions•Sludge management can be an important mitigation measure of carbon footprint in WSPs Due to regular influx of organic matter and nutrients, waste stabilization ponds (WSPs) can release considerable quantities of greenhouse gases (GHGs). To investigate the spatiotemporal variations of GHG emissions from WSPs with a focus on the effects of sludge accumulation and distribution, we conducted a bathymetry survey and two sampling campaigns in Ucubamba WSP (Cuenca, Ecuador). The results indicated that spatial variation of GHG emissions was strongly dependent on sludge distribution. Thick sludge layers in aerated ponds and facultative ponds caused substantial CO2 and CH4 emissions which accounted for 21.3% and 78.7% of the total emissions from the plant. Conversely, the prevalence of anoxic conditions stimulated the N2O consumption via complete denitrification leading to a net uptake from the atmosphere, i.e. up to 1.4±0.2 mg-N m−2 d−1. Double emission rates of CO2 were found in the facultative and maturation ponds during the day compared to night-time emissions, indicating the important role of algal respiration, while no diel variation of the CH4 and N2O emissions was found. Despite the uptake of N2O, the total GHG emissions of the WSP was higher than constructed wetlands and conventional centralized wastewater treatment facilities. Hence, it is recommended that sludge management with proper desludging regulation should be included as an important mitigation measure to reduce the carbon footprint of pond treatment facilities.
ISSN:0043-1354
1879-2448
DOI:10.1016/j.watres.2021.116858