Calculation of a Depth Correction Factor for the S-Layer Differential Transform

Magdel Combrinck

doi:10.1071/ASEG2007ab024

ISSN: 2202-0586
E-ISSN:

oa Calculation of a Depth Correction Factor for the S-Layer Differential Transform
Authors Magdel Combrinck^a
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^a Geotech Airborne Ltd., 121 Rosen Office Park 37 Invicta Rd, Halfway Gardens South Africa, [email protected]
Publisher: Australian Society of Exploration Geophysicists
Source: ASEG Extended Abstracts, Volume 2007, Issue ASEG2007 - 19th Geophysical Conference, Dec 2007, p. 1 - 4
DOI: https://doi.org/10.1071/ASEG2007ab024
- Published online: 01 Dec 2007

Abstract

Summary

The VTEM system developed and operated by Geotech Limited and Geotech Airborne Limited is a central loop configuration system lending itself perfectly to many traditional ground interpretation strategies. One of these is the S-layer (thin, conductive layer) differential transform which is used to generate resistivity-depth sections. An empirical study indicated that delineating conductors in a conductive half space necessitates the implementation of a scale factor in order to obtain the correct depths and conductivity values when applying the S-layer differential transform.

Based on an empirical approach, there was found to be an infinite number of depth correction factors that will still yield acceptable conductivity values and the need arose to explain the origin of this discrepancy and to find the correct depth correction factor. Three possible correction strategies were investigated based on comparison with synthetic data from models which have all shown that depths are overestimated by the S-layer differential transform. The most likely conclusion was that the physical assumptions regarding current distributions made in the S-layer transform lead to poor approximations of the conductors in a conductive half space. Assuming that the equivalent filament for the Slayer behaviour, as with the equivalent filament for the half space behaviour, does not coincide with the electric field maxima in the subsurface led to a plausible depth correction factor which was validated on various synthetic models.

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References

Eaton, P. A., and Hohmann, G. W., 1989, A rapid inversion technique for transient electromagnetic soundings. Phys. Earth Planet. Int., 53: 538-404
James, B. A., 1988, Detection of tunnels by transient electromagnetic subsurface imaging. U. S. Geol. Surv. Openfile Rep. 87-76.
Kaufman, A. A., and Keller, G. V., 1983, Frequency and Transient Soundings: Methods in Geochemistry and Geophysics 16. Elsevier Science Publishers, Amsterdam.
Macnae, J., and Lamontagne, Y., 1987, Imaging quasi-layered conductive structures by simple processing of transient electromagnetic data. Geophysics, 52: 545-554
Nabighian, M. N., and Macnae, J.C., 1991, Time Domain Electromagnetic prospecting Methods; in Nabighian, Misac N., Ed., Electromagnetic Methods in Applied Geophysics, Volume 2, Application: Soc. of Expl. Geophysicists: 427-520
Nekut, A. G., 1987, Direct inversion of time-domain electromagnetic data. Geophysics, 52: 1431-1435
Sidorov, V. A., and Tikshaev, V. V., 1969, Electrical prospecting with transient field in near zone: Saratov University (in Russian).
Smith, R. S., Edwards, R. N, and Buselli, G., 1994, An automatic technique for presentation of coincident-loop, impulse-response, transient, electromagnetic data: Geophysics, 59: 1542–1550
Spies, B. R., and Frischknecht, F. C., 1991, Electromagnetic Sounding; in Nabighian, Misac N., Ed., Electromagnetic Methods in Applied Geophysics, Volume 2, Application: Soc. of Expl. Geophysicists: 285-425
Tartaras, E., Zhdanov, M. S., Wada, K., Saito, A., and Hara, T., 2000, Fast imaging of TDEM data based on S-inversion: J. Appl. Geophys., 43: 15–32.
Wolfgram, P., Hyde, M., and Thomson, S., 1998, How to find localised conductors in GEOTEM data. Exploration Geophysics, 29: 665-670

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Article Type: Research Article

Keyword(s): CDI; depth correction; S-layer; TDEM; VTEM

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