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Electromagnetically Induced Transport in Water for Geoenvironmental Applications
Air sparging is a popular soil remediation technique that enables the removal of contaminants by diffusing air into soil. The removal process is, however, slow. The goal of this work is to study the effect of electromagnetic (EM) waves—with minimal heat generation—on transport mechanisms such as diffusion to improve airflow or contaminant transport to expedite the cleanup process using air sparging or similar technologies. This effect is studied through an experimental setup that examines the diffusion of a nonreactive dye in water under EM waves at a range of frequencies (50-200 MHz). The electric field was simulated using COMSOL Multiphysics for better three-dimensional (3D) visualization and analysis and then validated using the experimental measurements. A dielectrophoretic study was then performed using the simulated electric field. Various dye flows under EM stimulation at different frequencies were compared. At 65 MHz and 76 MHz, the dye flow was in the direction of the dielectrophoretic forces, which are believed to be the governing mechanism for the EM-stimulated dye transport.
Electromagnetically Induced Transport in Water for Geoenvironmental Applications
Air sparging is a popular soil remediation technique that enables the removal of contaminants by diffusing air into soil. The removal process is, however, slow. The goal of this work is to study the effect of electromagnetic (EM) waves—with minimal heat generation—on transport mechanisms such as diffusion to improve airflow or contaminant transport to expedite the cleanup process using air sparging or similar technologies. This effect is studied through an experimental setup that examines the diffusion of a nonreactive dye in water under EM waves at a range of frequencies (50-200 MHz). The electric field was simulated using COMSOL Multiphysics for better three-dimensional (3D) visualization and analysis and then validated using the experimental measurements. A dielectrophoretic study was then performed using the simulated electric field. Various dye flows under EM stimulation at different frequencies were compared. At 65 MHz and 76 MHz, the dye flow was in the direction of the dielectrophoretic forces, which are believed to be the governing mechanism for the EM-stimulated dye transport.
Electromagnetically Induced Transport in Water for Geoenvironmental Applications
Farid, Arvin (author) / Najafi, Atena (author) / Azad, Mahsa (author) / Browning, Jim (author) / Barney Smith, Elisa (author)
Geo-Congress 2014 ; 2014 ; Atlanta, Georgia
Geo-Congress 2014 Technical Papers ; 1576-1585
2014-02-24
Conference paper
Electronic Resource
English
Electromagnetically Induced Transport in Water for Geoenvironmental Applications
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