3D Gravity Modelling and Interpretation for the 1:250,000 Boulia Map Sheet, Queensland

Glenn Pears; Peter Fullagar; Phil Andrews

doi:10.1071/ASEG2001ab106

ISSN: 2202-0586
E-ISSN:

oa 3D Gravity Modelling and Interpretation for the 1:250,000 Boulia Map Sheet, Queensland
Authors Glenn Pears^a, Peter Fullagar^b and Phil Andrews^c
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^a Quantec Geoscience, , Brisbane, , Australia, [email protected] ^b Fullagar Geophysics, , Brisbane, , Australia, [email protected] ^c Quantec Geoscience, , Brisbane, , Australia, [email protected]
Publisher: Australian Society of Exploration Geophysicists
Source: ASEG Extended Abstracts, Volume 2001, Issue ASEG2001 - 15th Geophysical Conference, Dec 2001, p. 1 - 4
DOI: https://doi.org/10.1071/ASEG2001ab106
- Published online: 01 Dec 2001

Abstract

Sedimentary cover thickness strongly affects area selection for exploration in Proterozoic and Archean basement. Depth-to-basement is often inferred from gravity data. Interpretation of gravity is, however, fraught with ambiguity. The uncertainty can be minimised if all available information is exploited. In this paper drill logs, aeromagnetic depth-to-basement and basement geology interpretations, and a compilation of density values, as well as gravity data, are used to constrain a 3D density model of the Boulia 1:250,000 map area, Queensland.

Four recent events triggered this work: acquisition of 4km-spaced gravity data by the Queensland Department of Mines and Energy; publication of an aeromagnetic interpretation by AGSO; development of a computer program for constrained 3D inversion of gravity; and availability of sophisticated 3D geological modelling and visualisation software.

A 3D starting model was constructed, with basement topography, lithology, and density conforming to drill hole data and aeromagnetic interpretations. Paleozoic cover was represented as a layer of uniform density. The calculated gravity response of the starting model resembled the observed gravity in gross terms, but did not provide a satisfactory fit. Shallow magnetic basement correlated with low gravity. Denser basement units tended to be deeply buried.

The basement densities and elevations have been adjusted via inversion, to achieve a close fit to the data. In the areas of shallow basement (less than 1 km), basement depths have changed by up to 300m. In the NW corner and the central south of the map sheet, the interpreted depth of undivided granite basement has in places been reduced to 100m and 200m respectively.

The Boulia 3D density model represents a starting point for future refinement as additional holes are drilled and as new gravity and density data are collected. In particular, the gravity contribution from limestones in the cover sequence is not well understood. Additionally, combined magnetic and gravity inversion could further advance geological understanding of the area.

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References

Hone, I.G., Carberry, V.P. and Reith, H.G., 1987, Physical property measurements on rock samples from the Mt Isa Inlier, northwest Queensland: BMR Report 265, Canberra.
Mackey, T.E., Gunn, P.J., Meixner, A.J. and Blake, D.H., 1999, Boulia, interpreted geology, (1:250 000 scale map), AGSO.
Blake, D.H., 1987, Geology of the Mt Isa Inlier and environs, 1:500000 scale map: BMR, Canberra.
Casey, J.N., 1968, Boulia (Qld) 1:250000 Geological series -Explanatory notes: BMR, Canberra.
Fallon, G. N. and Busuttil, S.,1992, An appraisal of the Isa ore bodies: Exploration Geophysics, 23, 133-139.
Fullagar, P.K., Hughes, N.A. and Paine, J., 2000, Drilling-contrained 3D gravity interpretation: Exploration Geophysics, 31, pl7-23.
Mackey, T.E., Gunn, P.J., Meixner, A.J. and Blake, D.H., 2000, Mapping Australian geolgoy under cover: a case study applied to the Boulia and Springvale 1:250000 map sheets, Queensland: ASEG Preview No. 87, August 2000, pp28-32.
McGaughey, J. and Morrison, K., 2000, The common earth model: A revolution in exploration data integration: Mining Millenium 2000 Int. Conv. & Tech. Ex., Toronto., Conf. Proc.
Telford, W.M., Gerldart, L.P. and Sheriff, R.E., 1990, Applied Geophysics, 2n Ed: Cambridge University Press.

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Article Type: Research Article

Keyword(s): 3D modelling; Boulia; data integration; gravity; inversion; magnetics

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