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« Previous AbstractEvaluation of the kinetic oxidation of aqueous volatile organic compounds by permanganate    Next AbstractDissolution kinetics of volatile organic compound vapors in water: An integrated experimental and computational study »

J Environ Manage


Title:Evaluation of a horizontal permeable reactive barrier for preventing upward diffusion of volatile organic compounds through the unsaturated zone
Author(s):Mahmoodlu MG; Hassanizadeh SM; Hartog N; Raoof A; van Genuchten MT;
Address:"Utrecht University, Department of Earth Sciences, The Netherlands; Department of Watershed and Rangeland Management, Gonbad Kavous University, Iran. Electronic address: m.g.mahmnoodlu@gmail.com. Utrecht University, Department of Earth Sciences, The Netherlands. Utrecht University, Department of Earth Sciences, The Netherlands; KWR Watercycle Research Institute, Nieuwegein, The Netherlands. Utrecht University, Department of Earth Sciences, The Netherlands; Federal University of Rio de Janeiro, Department of Mechanical Engineering, Brazil"
Journal Title:J Environ Manage
Year:2015
Volume:20150828
Issue:
Page Number:204 - 213
DOI: 10.1016/j.jenvman.2015.08.025
ISSN/ISBN:1095-8630 (Electronic) 0301-4797 (Linking)
Abstract:"Permeable reactive barriers are commonly used to treat contaminant plumes in the saturated zone. However, no known applications of horizontal permeable reactive barriers (HPRBs) exist for oxidizing volatile organic compounds (VOCs) in the unsaturated zone. In this study, laboratory column experiments were carried out to investigate the ability of a HPRB containing solid potassium permanganate, to oxidize the vapors of trichloroethylene (TCE), toluene, and ethanol migrating upward from a contaminated saturated zone. Results revealed that an increase in initial water saturation and HPRB thickness strongly affected the removal efficiency of the HPRB. Installing the HPRB relatively close to the water table was more effective due to the high background water content and enhanced diffusion of protons and/or hydroxides away from the HPRB. Inserting the HPRB far above the water table caused rapid changes in pH within the HPRB, leading to lower oxidation rates. The pH effects were included in a reactive transport model, which successfully simulated the TCE and toluene experimental observations. Simulations for ethanol were not affected by pH due to condensation of water during ethanol oxidation, which caused some dilution in the HRPB"
Keywords:"Diffusion Ethanol/chemistry Groundwater/chemistry Hydrogen-Ion Concentration Models, Theoretical Oxidation-Reduction Toluene/chemistry Trichloroethylene/chemistry Volatile Organic Compounds/*chemistry Water Pollutants, Chemical/*chemistry Horizontal perme;"
Notes:"MedlineMahmoodlu, Mojtaba G Hassanizadeh, S Majid Hartog, Niels Raoof, Amir van Genuchten, Martinus Th eng Research Support, Non-U.S. Gov't England 2015/09/01 J Environ Manage. 2015 Nov 1; 163:204-13. doi: 10.1016/j.jenvman.2015.08.025. Epub 2015 Aug 28"

 
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