1887
ASEG2009 - 20th Geophysical Conference
  • ISSN: 2202-0586
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Abstract

Introduction

Transient electromagnetic (TEM) soundings have become one of die standard methods of environmental geophysics (Fittermann and Stewart, 1986; Buselli et al., 1990; Hoekstra and Blohm, 1990; Christensen and Sørensen, 1998; Auken et ah, 2006; Lane and Pracilio, 2000). Over die past decades, airborne TEM methods have found widespread use in hydrogeophysical investigations, making it possible to cover large areas in a cost-effective way. Several helicopterbome TEM systems have been developed and they now represent die most up-to-date method of airborne hydrogeophysical investigations, collecting 100,000s of data sets.

We present a fast approximate method for one-dimensional inversion of time domain electromagnetic data and apply it to Sky TEM helicopterbome data from the Toolibin Lake area of West Australia. The method is based on fast approximate forward computation of transient electromagnetic step responses and their derivatives with respect to die model parameters of a ID model. The inversion is carried out with multi-layer models in a state-of-the-art formulation of a least-squares iterative inversion scheme including explicit formulation of the model regularization through a model covariance matrix. The method is 50 times faster than conventional inversion for a layered earth model and produces model sections of concatenated ID models and contoured maps of mean conductivity in elevation intervals almost indistinguishable from those of conventional inversion.

To ensure lateral smoothness of the model sections and to avoid spurious artifacts in the mean conductivity maps, the Lateral Parameter Correlation method is applied to the results of the individual inversion models. In this way, well determined parameters are allowed to influence the more poorly determined parameters in the survey area.

Applied to the Sky TEM Toolibin data set, the inversion produces model sections and conductivity maps that reveal the distribution of conductivity in the area and thereby the distribution of salinity. This information is crucial for any remediation effort aimed at alleviating the salinity problems. The results are in accordance with previous results from other investigators.

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2009-12-01
2026-01-17

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References

  1. Auken E., Pellerin L., Christensen N.B. and Sørensen K. 2006. A survey of current trends in near-surface electrical and electromagnetic methods. Geophysics 71, G249-G260.
  2. Buselli G., Barber C., Davis G.B. and Salama R.B., 1990. Detection of groundwater contamination near waste disposal sites with transient electromagnetic and electrical methods, in Ward, S.H., Ed., Geotechnical and Environmental Geophysics, Vol. 2, Environmental and groundwater. Society of Exploration Geophysicists, Investigations in Geophysics, no. 5, 27-39.
  3. Christensen N.B., and Sorensen K.I., 1998. Surface and borehole electric and electromagnetic methods for hydrogeophysical investigations. European Journal of Environmental and Engineering Geophysics, Vol. 3, no 1, 75-90.
  4. Christensen N.B. 2002. A generic 1-D imaging method for transient electromagnetic data: Geophysics, 67, 438-447.
  5. Christensen N.B. and Tolboll R.J. 2008. A lateral model parameter correlation procedure for ID inverse modeling. Geophysical Prospecting, in print.
  6. Dogramaci S., George R., Mauger G. and Ruprecht J. Water balance and salinity trend, Toolibin catchment, Western Australia. http://www.naturebase.net/pdf/projects/salinity/toolibin/water_bal_salinity_hend.pdf.
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  8. George R. 1998. Evaluation of airborne geophysics for catchment management, Toolibin, Western Australia. 86 pp. National Airborne Geophysics Project.
  9. George R. and Dogramaci S. 2000. Toolibin—A life and death struggle for die last freshwater Wheatbelt lake, in: Hydro 2000 Interactive Hydrology, Volume 1: 3rd International Hydrology and Water Resources Symposium of the Institution of Engineers Australia, Perth, 20-23 November 2000, p. 733-738.
  10. Hoekstra P. and Blohm M.W. 1990. Case histories of time-domain electromagnetic soundings in environmental geophysics, in Ward, S.H., Ed., Geotechnical and Environmental Geophysics, Vol. 2, Environmental and groundwater: Society of Exploration Geophysicists, Investigations in Geophysics, no. 5, 1-16.
  11. Lane R. and Pracilio G. 2000. Visualisation of subsurface conductivity derived from airborne EM. SAGEEP 2000 Proceedings, 101-110.
  12. Reid J., Munday T. and Fitzpatrick A. 2007. High-resolution airborne electromagnetic surveying for dryland salinity management: The Toolibin Lake SkyTEM case study, WA. Extended abstract of the ASEG meeting, 2007, Perth, Western Australia
  13. Sørensen K.I. and Auken E. 2004. SkyTEM - A new high-resolution helicopter transient electromagnetic system. Exploration Geophysics 35, 191-199.
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  • Article Type: Research Article
Keyword(s): electromagnetic data; environmental.; fast inversion; helicopterbome; hydrogeophysical survey; time domain

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