Modelling the effects of ocean and sediments on electromagnetic fields: example from the gawler craton, south australia

Stephan Thiel; Graham Heinson

doi:10.1071/ASEG2009ab126

ISSN: 2202-0586
E-ISSN:

oa Modelling the effects of ocean and sediments on electromagnetic fields: example from the gawler craton, south australia
Authors Stephan Thiel^a and Graham Heinson^b
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^a The University of Adelaide, , [email protected] ^b The University of Adelaide, , [email protected]
Publisher: Australian Society of Exploration Geophysicists
Source: ASEG Extended Abstracts, Volume 2009, Issue ASEG2009 - 20th Geophysical Conference, Dec 2009, p. 1 - 6
DOI: https://doi.org/10.1071/ASEG2009ab126
- Published online: 01 Dec 2009

Abstract

Introduction

Magnetotelluric (MT) data have been frequently collected over the past few’ years in form of 2D and 3D surveys across much of the Gawler Craton. The increasing coverage of sites allows a regional analysis of the underlying resistivity distribution with the help of 2D and 3D inversion routines and helps constrain the delineation and nature of geological boundaries. Increasingly, the resistivity models have been combined with existing geological and geo chronological knowledge to analyse the tectonic evolution of the Gawler Craton.

The pitfall of large-scale regional analyses of MT data is the conductive influence of the ocean and thick sedimentary sequences on the MT responses. In the case of the Gawler Craton, the sediments, with resistivities of around 10Dm and thicknesses up to a few kilometers, contribute significantly to the inductive effect and can cause artefacts in the resistivity modeling. It is therefore essential to differentiate the inductive effect of the lithosphere and that of sediments and seawater.

We present a way of quantifying the sediment and ocean effects by means of 3D forward modeling of the electromagnetic fields associated with them. We show that such an analysis is highly beneficial to further modeling of lithospheric structures.

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References

Archie, G. (1942). The electrical resistivity log as an aid in determining some reservoir characteristics. Trans. A.I.M.E., 146, 54-62.
Borissova, I., & Symonds, P. (1997). Basins of Australia (Tech. Rep.). Australian Geological Survey Organisation.
Heinson, G., Direen, N., & Gill, R. (2006). Magnetotelluric evidence for a deep-crustal mineralizing system beneath the Olympic Dam iron oxide copper-gold deposit, southern Australia. Geology, 34, 573-576.
Maier, R., Heinson, G., Thiel, S., K.Selway, Gill, R., & Scrqggs, M. (2007). A 3D lithospheric electrical resistivity model of the Gawler Craton, Southern Australia. Applied Earth Science, 116,13-21.
Selway, K. (2006). Magnetotelluric experiments in central and southern Australia and their implications for tectonic evolution. PhD Thesis, University of Adelaide, Adelaide.
Siripunvarapom, W, Egbert, G., Lenbury, Y, & Uyeshima, M. (2005). Three-dimensional magnetotelluric inversion: data-space method. Physics of The Earth and Planetary Interiors, 150, 3-14.
Thiel, S. (2008). Modelling and inversion of magnetotelluric data for 2-D and 3-D itfiospherie structure, with application to obducted and subducted terranes. PhD thesis, University of Adelaide, Australia.
Thiel, S., & Heinson, G. (2006). A MT array on the edge of an old Australian craton: first results of strike analysis and modelling. In 18th Electromagnettc Induction Workshop Abstracts, El Vendrell Spain.

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Article Type: Research Article

Keyword(s): Gawler C rat on; inversion; magnetotellurics; modelling; ocean effect; sediments

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Abstract

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