Study on the Correlation between Dissolved Organic Carbon, Specific Oxygen Uptake Rate, and Exchangeable Nitrogen and the Performance of Granular Materials as Support Media for Methanotrophic Biofiltration

AbstractAnaerobic decomposition of organic materials in landfills is a key source of anthropogenic methane (CH4) emissions into the atmosphere. The use of methane biofilter (MB) technology for biological oxidation of CH4 into carbon dioxide (CO2) and water is an emerging area of interest for researc...

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Veröffentlicht in:	Journal of hazardous, toxic and radioactive waste toxic and radioactive waste, 2014-01, Vol.18 (1), p.11-15
Hauptverfasser:	Mancebo, Uriel, Hettiaratchi, J. Patrick A, Hurtado, Omar D
Format:	Artikel
Sprache:	eng
Schlagworte:	Carbon Carbon dioxide Granular materials Media Methane Nitrogen Oxygen consumption Technical Papers Uptakes
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creator	Mancebo, Uriel Hettiaratchi, J. Patrick A Hurtado, Omar D
description	AbstractAnaerobic decomposition of organic materials in landfills is a key source of anthropogenic methane (CH4) emissions into the atmosphere. The use of methane biofilter (MB) technology for biological oxidation of CH4 into carbon dioxide (CO2) and water is an emerging area of interest for researchers and practicing engineers. Studies were undertaken to assess the influence of dissolved organic carbon (DOC), specific oxygen uptake rate (SOUR), and exchangeable nitrogen (Nex) on different materials used as filter media in MBs. The obtained results showed that these parameters are strongly correlated with the CH4 oxidation potential observed for different porous materials. Low DOC, SOUR, and Nex values [318 parts per million (ppm), 168 ppm, and 228 mg O2/kg volatile solids/h, respectively] were associated with the highest methanotrophic activity rate observed in this study (3.6596 μmol CH4/gVS/d).
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Patrick A</creatorcontrib><creatorcontrib>Hurtado, Omar D</creatorcontrib><title>Study on the Correlation between Dissolved Organic Carbon, Specific Oxygen Uptake Rate, and Exchangeable Nitrogen and the Performance of Granular Materials as Support Media for Methanotrophic Biofiltration</title><title>Journal of hazardous, toxic and radioactive waste</title><description>AbstractAnaerobic decomposition of organic materials in landfills is a key source of anthropogenic methane (CH4) emissions into the atmosphere. The use of methane biofilter (MB) technology for biological oxidation of CH4 into carbon dioxide (CO2) and water is an emerging area of interest for researchers and practicing engineers. Studies were undertaken to assess the influence of dissolved organic carbon (DOC), specific oxygen uptake rate (SOUR), and exchangeable nitrogen (Nex) on different materials used as filter media in MBs. 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subjects	Carbon Carbon dioxide Granular materials Media Methane Nitrogen Oxygen consumption Technical Papers Uptakes
title	Study on the Correlation between Dissolved Organic Carbon, Specific Oxygen Uptake Rate, and Exchangeable Nitrogen and the Performance of Granular Materials as Support Media for Methanotrophic Biofiltration
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