Assessing the spatial and temporal variability of greenhouse gas emissions from different configurations of on-site wastewater treatment system using discrete and continuous gas flux measurement

Global emissions linked to wastewater treatment are estimated to account for up to 1.5 % of total greenhouse gas (GHG) emissions globally. However, few studies have measured GHG emissions from domestic on-site treatment systems (DWWTSs) directly. In this study, two DWWTSs were monitored for 446 d an...

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Bibliographic Details
Published in:Biogeosciences 2022-02, Vol.19 (4), p.1067-1085
Main Authors: Knappe, Jan, Somlai, Celia, Gill, Laurence W
Format: Article
Language:English
Subjects:
Air pollution
Biogeochemistry
Biological activity
Carbon dioxide
Carbon dioxide emissions
Configuration management
Design
Effluents
Emission measurements
Emissions
Environmental aspects
Environmental factors
Fluctuations
Fluxes
Greenhouse effect
Greenhouse gases
Heterogeneity
Intergovernmental Panel on Climate Change
Measurement
Methane
Moisture content
Nitrous oxide
Onsite
Purification
Septic tanks
Sewage
Sewage disposal
Soil
Soil temperature
Soil treatment
Soil water
Systems design
Temporal variability
Temporal variations
Wastewater treatment
Water consumption
Water content
Water treatment
Water use
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Summary:Global emissions linked to wastewater treatment are estimated to account for up to 1.5 % of total greenhouse gas (GHG) emissions globally. However, few studies have measured GHG emissions from domestic on-site treatment systems (DWWTSs) directly. In this study, two DWWTSs were monitored for 446 d and > 42 000 gas flux measurements were conducted using both discrete spot measurements and continuous flux chamber deployments. The observed GHG fluxes from biological activity in the soil and water phase were found to be highly spatially and temporally variable and correlated to environmental factors, water usage patterns and system design. In total, the results show that a septic tank discharging effluent into a well-designed soil treatment unit is estimated to emit a net 9.99 kg-CO2eq.cap-1yr-1, with approximately 63 %, 27 % and 10 % of the total CO2-equivalent net emissions in the form of CO2, CH4 and N2O, respectively. Emissions from the septic tank surface contributed over 50 % of total emissions and tended to be strongly underestimated by one-off discrete measurements, especially when episodic ebullitive events are to be considered. Fluxes from the soil treatment unit (STU) stemmed from both the soil surface and the vent system. Soil fluxes were mostly influenced by temperature but peaked regularly under conditions of rapidly changing soil water content. Vent fluxes were mostly governed by effluent, quality and a low number of high-emission events were responsible for the majority of total observed vent emissions. Owing to the strong overall spatial and temporal heterogeneity of observed fluxes from DWWTSs across all modules, future studies should focus on continuous deployments of a number of flux chambers over discrete measurements to accurately assess GHG emissions from on-site systems. This study also provided insights into managing GHG emissions from DWWTSs by different system configuration design, as well as indicating that the current IPCC emission factors for CH4 and N2O significantly overestimate emissions for on-site wastewater treatment systems.
ISSN:1726-4189
1726-4170
1726-4189
DOI:10.5194/bg-19-1067-2022