Carbon and nitrogen gaseous fluxes from subsurface flow wetland buffer strips at mesocosm scale in East Africa

•Use of Cyperus papyrus under batch hydraulic loading can enhance aerobic conditions in sub-surface flow constructed wetlands.•Planted VF and HF exhibited significant nitrification rates with potential for coupled denitrification.•Induced aerobic conditions enhanced high emission of CO2, but imposed...

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Bibliographic Details
Published in:Ecological engineering 2015-12, Vol.85, p.173-184
Main Authors: Bateganya, Najib Lukooya, Mentler, Axel, Langergraber, Guenter, Busulwa, Henry, Hein, Thomas
Format: Article
Language:English
Subjects:
Carbon
Carbon dioxide
Cyperus papyrus
Degradation
East Africa
Ecology
Fluxes
Gas fluxes
Hydraulics
Nitrification
Nitrogen
Nitrous oxides
Organic matter
Subsurface flow
Wetland buffer strips
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Summary:•Use of Cyperus papyrus under batch hydraulic loading can enhance aerobic conditions in sub-surface flow constructed wetlands.•Planted VF and HF exhibited significant nitrification rates with potential for coupled denitrification.•Induced aerobic conditions enhanced high emission of CO2, but imposed significant inhibition of CH4 fluxes. This study investigated carbon (CH4, CO2) and nitrogen (N2O) gaseous fluxes as finger prints for microbial wastewater treatment processes in vertical (VF) and horizontal (HF) subsurface flow mesocosms, planted with Cyperus papyrus and operated under batch hydraulic loading. The closed chamber method was used to measure gaseous emissions for 12 weeks (April–June 2014) in Kampala, Uganda. Organic matter (OM) (BOD5 and COD) and inorganic nitrogen (NH4+ and NO3−) nutrient concentrations were monitored to estimate OM degradation rates and potential nitrification and denitrification. The highest mean CH4 flux (mg CH4Cm−2h−1) was 38.3±3.3 in unplanted HF compared to the lowest (3.3±0.4) established in planted VF mesocosms. CO2 fluxes (mg CO2Cm−2h−1) were significantly higher (P0.05) between the planted HF (2213.5±122.4) and VF (2272.8±191.0) mesocosms. The high CO2 flux was attributed to efficient degradation of the inflow organic carbon facilitated by sufficient oxygen supply especially in the planted mesocosms. Although N2O flux was relatively higher in HF mesocosms, it did not vary significantly (P>0.05) in all treatments. Generally the results indicated significant nitrification, especially in the planted mesocosms. However, high fluxes of N2O comparable to other denitrifying CWs suggested potential for coupled nitrification and denitrification in these systems. Overall, compared to CH4 and N2O, CO2 was found to be the most significant gaseous flux under induced aerobic conditions enhanced by use of C. papyrus plants and an intermittent loading regime.
ISSN:0925-8574
1872-6992
DOI:10.1016/j.ecoleng.2015.09.081