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Characterizing a low-velocity waveguide using crosshole GPR full-waveform inversion

For accurate prediction of flow and contaminant transport a detailed quantification of the local spatial hydraulic conductivity is necessary. In particular, decimeter-scale high contrast layers caused by increased porosity or clay content are important because they can have a dominant effect on solu...

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Bibliographic Details
Main Authors: Klotzsche, A., van der Kruk, J., Vereecken, H., Meles, G. A.
Format: Conference Proceeding
Language:English
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Summary:For accurate prediction of flow and contaminant transport a detailed quantification of the local spatial hydraulic conductivity is necessary. In particular, decimeter-scale high contrast layers caused by increased porosity or clay content are important because they can have a dominant effect on solute transport. Such embedded layers when characterized by high dielectric permittivity can act as low-velocity electromagnetic waveguides and be readily identified and characterized using high-frequency crosshole GPR. We show by means of a GPR field example from a hydrological test site in Switzerland that the full-waveform inversion, which exploits the full information content of the data, is able to image a sub-wavelength thickness dipping low-velocity wave-guiding layer. Further, we show an approach to identify low-velocity waveguides from the measured data by analyzing the amplitude and energy behavior within the data. For transmitters present within the waveguide, high amplitude elongated wave-trains are detected for receivers straddling the waveguide depth range, with significantly larger amplitudes than on receivers outside the low-velocity layer, whereas transmitters outside the waveguide show an energy minimum for receivers within the waveguide.
DOI:10.1109/ICGPR.2012.6254830