Using Potential Field Data for Petroleum Exploration Targeting, Amadeus Basin, Australia

Mike Dentith; Duncan Cowan

doi:10.1081/22020586.2010.12041858

ISSN: 2202-0586
E-ISSN:

oa Using Potential Field Data for Petroleum Exploration Targeting, Amadeus Basin, Australia
Authors Mike Dentith^a and Duncan Cowan^b
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^a Centre for Exploration TargetingThe University of Western Australia, 35 Stirling Highway Crawley Western Australia, 6009, [email protected] ^b Cowan Geodata Services, 12 Edna Road Dalkeith Western Australia, 6009, [email protected]
Publisher: Australian Society of Exploration Geophysicists
Source: ASEG Extended Abstracts, Volume 2010, Issue ASEG2010 - 21st Geophysical Conference, Dec 2010, p. 1 - 4
DOI: https://doi.org/10.1081/22020586.2010.12041858
- Published online: 01 Dec 2010

Abstract

Summary

The Amadeus Basin, a large Proterozoic basin located in central Australia, is the least explored onshore petroleumbearing basin with proven reserves in Australia. The size and remoteness of the Amadeus Basin makes ground exploration expensive, but airborne gravity and magnetic surveys have been shown to be capable of resolving intra-basin structures in sufficient detail to allow prospective areas to be identified.

In the western part of the basin the Gillen Petroleum System is considered most significant: This system has the important characteristic that the source is stratigraphically higher than the reservoir. Thin skinned deformation is expected at the source level and above, with detachments at evaporitic horizons, but deformation of the reservoir is expected to be thick-skinned. This model can form the basis for predicting potential field responses. The most prospective areas are where (i) gravity suggests basement (and reservoir) is shallow, (ii) magnetics maps fold-thrust complexes (structural trap), (iii) these features occur adjacent to gravity lows, indicative of significant thicknesses of basin fill (source at depth and below reservoir). Faults at the margins of the depocentre (mapped using magnetic data) provide a possible migration path for the hydrocarbons.

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References

Burgess, J.M., et al., 2002. New perspectives of the Amadeus Basin, northern Territory. PESA Journal, 29, 14-23.
Foss, C. and Marshall, T.R., 2005. Beaten with a blunt object, can we get more out of geophysics in the Amadeus Basin? (abstract), Central Australian Basins Symposium.
Haines, P.W., Hand, M. and Sandiford, M. 2001. Palaeozoic synorogenic sedimentation in central and northern Australia: a review of distribution and timing with implications for the evolution of intracontinental orogens. Australian Journal of Earth Sciences, 48, 911-928.
Lindsay, J.F. and Korsch, R.J., 1991. The evolution of the Amadeus Basin, central Australia. In, Korsch, R.J. and Kennard, J.M., (Editors), Geological and Geophysical Studies in the Amadeus Basin, Central Australia, BMR Bulletin 236, 7-32.
Lindsay, J.F., Kruse, P.D., and five others, 2005. The Neoproterozoic–Cambrian record in Australia: a stable isotope study. Precambrian Research 143, 113-133.
Schroder, R.J. and Gorter, J.D., 1984. A review of the recent exploration and hydrocarbon potential of the Amadeus Basin, Northern Territory. The APEA Journal, 19-41.
Shaw, R.D., Korsch, R.J., Wright, C. and Goleby, B.R., 1991. Seismic interpretation and thrust tectonics of the Amadeus Basin, central Australia, along the MBR regional seismic line. BMR Bulletin 236, 385-408.

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Article Type: Research Article

Keyword(s): aerogravity; aeromagnetics; Amadeus Basin; petroleum exploration; Western Australia

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