Evaluating Methane Oxidation Efficiencies in Experimental Landfill Biocovers by Mass Balance and Carbon Stable Isotopes

Biocovers are an alternative for mitigating fugitive and residual emissions of methane from landfills. In this study, we evaluated the performance of two experimental passive methane oxidation biocovers (PMOBs) constructed within the existing final cover of the St-Nicéphore landfill (Quebec, Canada)...

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Bibliographic Details
Published in:Water, air, and soil pollution air, and soil pollution, 2012-11, Vol.223 (9), p.5623-5635
Main Authors: Capanema, Marlon A., Cabral, Alexandre R.
Format: Article
Language:English
Subjects:
Air temperature
Analysis
Atmospheric Protection/Air Quality Control/Air Pollution
Bacteria
Biogas
Biomass energy
Carbon dioxide
Climate Change/Climate Change Impacts
Density
Earth and Environmental Science
Environment
Environmental monitoring
Fractionation
Gases
Hydrogeology
Isotopes
Landfill
Landfills
Methane
Oxidation
Oxidation-reduction reaction
Refuse and refuse disposal
Soil Science & Conservation
Stable isotopes
Studies
Vegetation
Waste disposal sites
Waste management
Water Quality/Water Pollution
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Summary:Biocovers are an alternative for mitigating fugitive and residual emissions of methane from landfills. In this study, we evaluated the performance of two experimental passive methane oxidation biocovers (PMOBs) constructed within the existing final cover of the St-Nicéphore landfill (Quebec, Canada). The biocovers were fed in a controlled manner with raw biogas and surface fluxes were obtained using static chambers. This enabled calculating mass balances of CH 4 and oxidation efficiencies ( f o_MB ). Most of the time, f o_MB  ≥ 92 % were obtained for loadings as high as 818 g CH 4  m −2  day −1 (PMOB-2) and 290 g CH 4  m −2  day −1 (PMOB-3B). The lowest efficiencies ( f o_MB  = 45.5 % and 34.0 %, respectively) were obtained during cold days (air temperature ~0 °C). Efficiencies were also calculated using stable isotopes ( f o_SI ); the highest f o_SI were 66.4 % for PMOB-2 and 87.3 % for PMOB-3B; whereas the lowest were 18.8 % and 23.1 %, respectively. However, f o_SI values reflect CH 4 oxidation up to a depth of 0.10 m, which may partly explain the difference in regards to mass balance-derived efficiencies. Indeed, it is expected that a significant fraction of the total CH 4 oxidation occurs within the zone near the surface, where there is greater O 2 availability. The influence of the values of fractionation factors α ox and α trans were also evaluated in this paper.
ISSN:0049-6979
1573-2932
DOI:10.1007/s11270-012-1302-6