Biocover Performance of Landfill Methane Oxidation: Experimental Results

Cabral, Alexandre R.; Moreira, Joao Fernandes; Jugnia, Louis‐B.

doi:10.1061/(asce)ee.1943-7870.0000182

Cited by 44 publications

(31 citation statements)

References 35 publications

(32 reference statements)

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“…Another caveat is that the application of the method to field profiles may lead to an underestimation of the total oxidation efficiency if a relevant share of the oxidation occurs very near the surface (Cabral et al, 2009(Cabral et al, , 2010, while the top most samples of gas profiles are taken from below this upper crust. It is thus advisable to collect samples from as shallow depths as possible.…”

Section: Limitations Of the Proposed Methodsmentioning

confidence: 99%

“…Setup of the first laboratory column study using mineral soils. (Cabral et al, 2009(Cabral et al, , 2010. The gravel-sand-compost mixture was compacted to 77% of the Proctor, again to simulate actual field conditions.…”

Section: Laboratory Column Studies and Materialsmentioning

confidence: 99%

“…This is particularly important when at some point gas extraction systems are turned off, while biogas production may continue for several decades, and alternative measures are required to reduce emissions. However, a reliable quantification of methane removal rates is possible only when the magnitude of the fluxes into and out of the cover are known -which rarely is the case (Cabral et al, 2009(Cabral et al, , 2010) -or estimated (e.g. Einola et al, 2008Einola et al, , 2009.…”

Section: Introductionmentioning

confidence: 99%

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Can soil gas profiles be used to assess microbial CH4 oxidation in landfill covers?

Gebert

Röwer

Scharff³

et al. 2011

Waste Management

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A method is proposed to estimate CH(4) oxidation efficiency in landfill covers, biowindows or biofilters from soil gas profile data. The approach assumes that the shift in the ratio of CO(2) to CH(4) in the gas profile, compared to the ratio in the raw landfill gas, is a result of the oxidation process and thus allows the calculation of the cumulative share of CH(4) oxidized up to a particular depth. The approach was validated using mass balance data from two independent laboratory column experiments. Values corresponded well over a wide range of oxidation efficiencies from less than 10% to nearly total oxidation. An incubation experiment on 40 samples from the cover soil of an old landfill showed that the share of CO(2) from respiration falls below 10% of the total CO(2) production when the methane oxidation capacity is 3.8 μg CH(4)g(dw)(-1)h(-1) or higher, a rate that is often exceeded in landfill covers and biofilters. The method is mainly suitable in settings where the CO(2) concentrations are not significantly influenced by processes such as respiration or where CH(4) loadings and oxidation rates are high enough so that CO(2) generated from CH(4) oxidation outweighs other sources of CO(2). The latter can be expected for most biofilters, biowindows and biocovers on landfills. This simple method constitutes an inexpensive complementary tool for studies that require an estimation of the CH(4) oxidation efficiency values in methane oxidation systems, such as landfill biocovers and biowindows.

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Section: Limitations Of the Proposed Methodsmentioning

confidence: 99%

Section: Laboratory Column Studies and Materialsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Can soil gas profiles be used to assess microbial CH4 oxidation in landfill covers?

Gebert

Röwer

Scharff³

et al. 2011

Waste Management

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“…Biogas mass fluxes at the surface were calculated based on the results obtained using Equation 1 (according to Cabral et al, 2010a andPerera et al, 2002), corrected for the standard temperature and pressure (STP).…”

Section: Surface Methane Mass Flux Calculationsmentioning

confidence: 99%

“…Several studies have shown that a passive biosystem (where the biogas passes through the cover naturally, without pumping it) installed in the cover system (interim or fi-nal) can be a very effective complement to active systems in reducing fugitive emissions of methane and odorous substances (Abichou et al, 2006a;Cabral et al, 2010a;Capanema et al, 2013;Capanema et al, 2014;Geck et al, 2016;Lucernoni et al, 2016;Roncato and Cabral, 2012;Sadasivam and Reddy, 2014;Scheutz et al, 2009). Most of these studies documented the performance of passive biosystems in temperate climates, while (to the authors' knowledge) no field-scale studies have been performed to document the performance of passive biosystems in Brazil (a tropical country) and employing residual soils.…”

Section: Introductionmentioning

confidence: 99%

Fugitive Methane Emissions From Two Experimental Biocovers Constructed With Tropical Residual Soils: Field Study Using a Large Flux Chamber

et al. 2019

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This study aimed at assessing the response of two experimental passive methane oxidation biocovers (PMOB) installed in a Brazilian landfill located in Guarapuava, State of Paraná. The PMOBs covered an area of 18 m² each, and were 0.70-m-thick. The first PMOB (control subarea) was constructed using the same soil used to cover closed landfill cells, i.e. a typical residual soil. The second PMOB (enriched subarea) was constructed with a mixture of the residual soil and mature compost, with a resulting organic matter content equal to 4.5%. CH 4 and CO 2 surface fluxes were measured in a relatively large (4.5 m²) static chamber. CH 4 , CO 2 and O 2 concentrations were also measured at different depths (0.10, 0.20, 0.25 and 0.30 m) within PMOBs. The concentrations from the raw biogas were also measured. Methane oxidation efficiencies (Eff ox) were estimated based on the CO 2 /CH 4 ratio. The average CH 4 and CO 2 concentrations in the raw biogas (42% and 32%, respectively) for the 16 campaigns corroborated those typically found in Brazilian landfills. Lower CH 4 fluxes were obtained within the enriched subarea (average of 20 g.m-2 .d-1), while the fluxes in the control subarea averaged 34 g.m-2 .d-1. Eff ox values averaged 42% for the control subarea and 80% for the enriched one. The results indicate that there is a great potential to reduce landfill gas (LFG) emissions by using passive methane oxidation biosystems composed of enriched substrates (with a higher content of organic matter).

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Numerical Analysis of Water and Gas Migration Within a Landfill Biocover Using a Two-Phase Flow Model

Sun,

2024

Environmental Science and Engineering

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Biocover Performance of Landfill Methane Oxidation: Experimental Results

Cited by 44 publications

References 35 publications

Can soil gas profiles be used to assess microbial CH4 oxidation in landfill covers?

Can soil gas profiles be used to assess microbial CH4 oxidation in landfill covers?

Fugitive Methane Emissions From Two Experimental Biocovers Constructed With Tropical Residual Soils: Field Study Using a Large Flux Chamber

Numerical Analysis of Water and Gas Migration Within a Landfill Biocover Using a Two-Phase Flow Model

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