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RESEARCH ARTICLE

Heat flow data from the southeast of South Australia: distribution and implications for the relationship between current heat flow and the Newer Volcanics Province

Chris Matthews 1 2 3 4 5 Graeme Beardsmore 4 Jim Driscoll 4 Nicky Pollington 4
+ Author Affiliations
- Author Affiliations

1 School of Geosciences, Monash University, Clayton, Vic. 3800, Australia.

2 South Australian Centre for Geothermal Energy Research, The University of Adelaide, Adelaide, SA 5005, Australia.

3 Panax Geothermal Ltd, Level 2, 139 Frome Street, Adelaide, SA 5000, Australia.

4 Hot Dry Rocks Pty Ltd, PO Box 251, South Yarra, Vic. 3141, Australia.

5 Corresponding author. Email: cmatthews70@yahoo.com.au

Exploration Geophysics 44(2) 133-144 https://doi.org/10.1071/EG12052
Submitted: 20 August 2012  Accepted: 12 March 2013   Published: 22 April 2013

Abstract

This paper presents the results of 34 new heat flow estimates taken in 2004 from 16 water bores and 18 petroleum exploration wells in the western Otway Basin. The average estimated heat flow measured across the study area is 65.6 ± 9.4 mW/m2, with a range of 42–90 mW/m2. There are three recognisable sectors within the study area where heat flow is slightly elevated relative to the background levels. These sectors can be broadly classified as Mount Schank (73.5 ± 0.5 mW/m2), Mount Burr (71.2 ± 7.6 mW/m2) and Beachport (78.3 ± 10.4 mW/m2). Thermal conductivity values for each unit involved in heat flow estimation were determined from laboratory measurements on representative core using a divided bar apparatus. Borehole thermal conductivity profiles were then developed in this study by assigning a constant value of conductivity to each geological formation. The process of collecting temperature data involved measuring temperature profiles for 16 water bores using a cable, winch and thermistor, and compiling well completion temperature data from 18 petroleum wells. The precision of temperature data was higher in the water bores (continuous logs) than in the petroleum wells (largely bottom-of-hole temperature estimates). Inversion heat flow modelling suggests heterogeneous heat flow at 6000 m depth, with two zones where vertical heat flow might exceed 90 mW/m2, and several zones where vertical heat flow might be as low as 40 mW/m2. Therefore, while slightly higher surface heat flow does coincide with some of the volcanic centres, heterogeneous basement heat production is a more likely explanation, as there are no heat flow anomalies greater than 5–10 mW/m2 associated with the Pleistocene–Recent Newer Volcanics Province. The distribution of heat flow in south-east South Australia is most simply explained by non-volcanic phenomena.

Key words: Australia, Delamerian Fold Belt, geothermal modelling, heat flow, Newer Volcanics Province, Otway Basin, thermal conductivity, thermal gradient.


References

Beardsmore, G. R., 2005, Thermal modelling of the hot dry rock geothermal resource beneath GEL99 in the Cooper Basin: Proceedings of the World Geothermal Congress, Antalya, Turkey, 24–29 April, 2005.

Beardsmore, G. R., and Cull, J. P., 2001, Crustal heat flow: a guide to measurement and modelling: Cambridge University Press, 324.

Boult, P. J., 2002, Summary and introduction, in P. J. Boult, and J. E. Hibburt, eds., The petroleum geology of South Australia, vol. 1: Otway Basin, 2nd edition: Department of Primary Industries and Resources (South Australia), Petroleum Geology of South Australia Series, Vol. 1, Ch. 1.

Cas, R. A. F. (Coordinator), 1989, Physical volcanology, in R. W. Johnson, J. Knutson, and S. R. Taylor, eds., Intraplate volcanism in eastern Australia and New Zealand: Cambridge University Press, 55–87.

Coblentz, D. D., Sandiford, M., Richardson, R. M., Zhou, S., and Hillis, R., 1995, The origins of the intraplate stress field in continental Australia: Earth and Planetary Science Letters, 133, 299–309
The origins of the intraplate stress field in continental Australia:Crossref | GoogleScholarGoogle Scholar | 1:CAS:528:DyaK2MXnsFeqtbs%3D&md5=628a431da674aaef3594ea33028f5656CAS |

Denham, D., Weekes, J., and Krayshek, C., 1981, Earthquake evidence for compressive stress in the Southeast Australian crust: Journal of the Geological Society of Australia, 28, 323–332
Earthquake evidence for compressive stress in the Southeast Australian crust:Crossref | GoogleScholarGoogle Scholar |

Dickinson, J. A., Wallace, M. W., Holdgate, G. R., Gallagher, S. J., and Thomas, L., 2002, Origin and timing of the Miocene-Pliocene unconformity in Southeast Australia: Journal of Sedimentary Research, 72, 288–303
Origin and timing of the Miocene-Pliocene unconformity in Southeast Australia:Crossref | GoogleScholarGoogle Scholar |

Gallagher, S. J., and Holdgate, G., 2000, The palaeogeographic and palaeoenvironmental evolution of a Palaeogene mixed carbonate-siliciclastic cool-water succession in the Otway Basin, Southeast Australia: Palaeogeography, Palaeoclimatology, Palaeoecology, 156, 19–50
The palaeogeographic and palaeoenvironmental evolution of a Palaeogene mixed carbonate-siliciclastic cool-water succession in the Otway Basin, Southeast Australia:Crossref | GoogleScholarGoogle Scholar |

Geoscience Australia, 2012, Otway Basin. Available at www.ga.gov.au/oceans/sa_Otway.jsp (accessed 20 August 2012).

Hamza, V. M., 1979, Variation of continental mantle heat flow with age: possibility of discriminating between thermal models of the lithosphere: Pure and Applied Geophysics, 117, 65–74

Hillis, R. R., Enever, J. R., and Reynolds, S. D., 1999, In situ stress field of eastern Australia: Australian Journal of Earth Sciences, 46, 813–825
In situ stress field of eastern Australia:Crossref | GoogleScholarGoogle Scholar |

Hot Dry Rocks Pty Ltd, 2012, Geothermal systems assessment of the Limestone Coast geothermal project, South Australia: Unpublished report for Panax Geothermal Ltd, 206 pp.

Houseman, G. A., Cull, J. P., Muir, P. M., and Paterson, H. L., 1989, Geothermal signatures and uranium ore deposits on the Stuart Shelf of South Australia: Geophysics, 54, 158–170
Geothermal signatures and uranium ore deposits on the Stuart Shelf of South Australia:Crossref | GoogleScholarGoogle Scholar |

Jenkins, R. J. F., and Sandiford, M., 1992, Observations on the tectonic evolution of the southern Adelaide Fold Belt: Tectonophysics, 214, 27–36
Observations on the tectonic evolution of the southern Adelaide Fold Belt:Crossref | GoogleScholarGoogle Scholar |

Jensen-Schmidt, B., Cockshell, C. D., and Boult, P. J., 2002, Structural and tectonic setting, in P. J. Boult, and J. E. Hibburt, eds., The petroleum geology of South Australia, vol. 1: Otway Basin, 2nd edition: Department of Primary Industries and Resources (South Australia), Petroleum Geology of South Australia Series, Vol. 1, Ch. 5.

Johnson, R. W., and Wellman, P. (Coordinators), 1989, Framework for volcanism, in R. W. Johnson, J. Knutson, and S. R. Taylor, eds., Intraplate volcanism in eastern Australia and New Zealand: Cambridge University Press, 1–53.

Jorand, C., Krassay, A., and Hall, L., 2010, Otway Basin hot sedimentary aquifers and SEEBASE Project: Report to PIRSA-GA-DPI Vic.

Lachenbruch, A. H., and Brewer, M. C., 1959, Dissipation of the temperature effect of drilling a well in Arctic Alaska: U.S. Geological Survey Bulletin, 1083-C, 73–109

Li, A., McGowran, B., and White, M. R., 2000, Sequences and biofacies packages in the mid-Cenozoic Gambier Limestone, South Australia: reappraisal of foraminiferal evidence: Australian Journal of Earth Sciences, 47, 955–970
Sequences and biofacies packages in the mid-Cenozoic Gambier Limestone, South Australia: reappraisal of foraminiferal evidence:Crossref | GoogleScholarGoogle Scholar |

Love, A. J., Herczeg, A. L., Armstrong, D., Stadter, F., and Mazor, E., 1993, Groundwater flow regime within the Gambier Embayment of the Otway Basin, Australia: evidence from hydraulics and hydrochemistry: Journal of Hydrology, 143, 297–338
Groundwater flow regime within the Gambier Embayment of the Otway Basin, Australia: evidence from hydraulics and hydrochemistry:Crossref | GoogleScholarGoogle Scholar | 1:CAS:528:DyaK3sXlsVKjsLc%3D&md5=7866d4c00a031d4e1707b80fc3690432CAS |

Matthews, C. G., 2009, Geothermal energy prospectivity of the Torrens Hinge Zone: evidence from new heat flow data: Exploration Geophysics, 40, 288–300
Geothermal energy prospectivity of the Torrens Hinge Zone: evidence from new heat flow data:Crossref | GoogleScholarGoogle Scholar | 1:CAS:528:DC%2BD1MXhtFCktb%2FP&md5=efbc06517bcd3dfa2fcbed4fa356f873CAS |

Matthews, C. G., and Beardsmore, G. R., 2007, New heat flow data from southeastern South Australia: Exploration Geophysics, 38, 260–269
New heat flow data from southeastern South Australia:Crossref | GoogleScholarGoogle Scholar |

Miller, J. McL., Norvick, M. S., and Wilson, C. J. L., 2002, Basement controls on rifting and the associated formation of ocean transform faults: Cretaceous continental extension of the southern margin of Australia: Tectonophysics, 359, 131–155
Basement controls on rifting and the associated formation of ocean transform faults: Cretaceous continental extension of the southern margin of Australia:Crossref | GoogleScholarGoogle Scholar |

Morton, J. G. G., and Drexel, J. F., eds.,1995, Petroleum geology of South Australia. Vol. 1 Otway Basin: Petroleum Division, SA Department of Mines and Energy.

Murray-Wallace, C. V., Belperio, A. P., and Cann, J. H., 1998, Quaternary neotectonism and intra-plate volcanism: the Coorong to Mount Gambier coastal plain, southeastern Australia— a review, in I. S. Stewart, and C. Vita-Finzi, eds., Coastal tectonics: Geological Society Special Publications, 146, 255–267.

O’Brien, G. W., Reeves, C. V., Milligan, P. R., Morse, M. P., Alexander, E. M., Willcox, J. B., Yunxuan, Z., Finlayson, D. M., and Brodie, R. C., 1994, New ideas on the rifting history and structural architecture of the Western Otway Basin: evidence from the integration of aeromagnetic, gravity and seismic data: APEA Journal, 34, 529–554

Perincek, D., and Cockshell, C. D., 1995, The Otway Basin: Early Cretaceous rifting to Neogene inversion: APEA Journal, 35, 451–466

Sandiford, M., 2003a, Neotectonics of SE Australia and the origin of the intraplate stress field, in C. G. Skilbeck, and T. C. T. Hubble, eds., Understanding Planet Earth: searching for a sustainable future: Geological Society of Australia, Abstracts of the 15th Australian Geological Convention, 59, 435.

Sandiford, M., 2003b, Geomorphic constraints on the late Neogene tectonics of the Otway Range, Victoria: Australian Journal of Earth Sciences, 50, 69–80
Geomorphic constraints on the late Neogene tectonics of the Otway Range, Victoria:Crossref | GoogleScholarGoogle Scholar |

Sandiford, M., Frederiksen, S., and Braun, J., 2003, The long-term thermal consequences of rifting: implications for basin reactivation: Basin Research, 15, 23–43
The long-term thermal consequences of rifting: implications for basin reactivation:Crossref | GoogleScholarGoogle Scholar |

Sheard, M. J., and Nicholls, I. A., 1989, Mount Gambier sub-province, in R. W. Johnson, J. Knutson, and S. R. Taylor, eds., Intraplate volcanism in eastern Australia and New Zealand: Cambridge University Press, 142.

Sprigg, R. C., 1959, Presumed submarine volcanic activity near Beachport, south-east South Australia: Transactions of the Royal Society of South Australia, 82, 195–203

Sutherland, F. L., 1981, Migration in relation to possible tectonic and regional controls in eastern Australian volcanism: Journal of Volcanology and Geothermal Research, 9, 181–213
Migration in relation to possible tectonic and regional controls in eastern Australian volcanism:Crossref | GoogleScholarGoogle Scholar |

Torrens Energy Limited, 2008, 780 000 PJ Inferred Resource, Parachilna Project, South Australia. ASX announcement 20 August 2008. Available at http://www.asx.com.au/asxpdf/20080820/pdf/31bsp0dcmt4sw0.pdf (first accessed 21 August 2008).

Turner, S. P., Foden, J. D., and Morrison, R. S., 1992, Derivation of some A-type magmas by fractionation of basaltic magma: an example from the Padthaway Ridge, South Australia: Lithos, 28, 151–179
Derivation of some A-type magmas by fractionation of basaltic magma: an example from the Padthaway Ridge, South Australia:Crossref | GoogleScholarGoogle Scholar | 1:CAS:528:DyaK38XlsFCkt78%3D&md5=faa6c78cfb739875cfdc79b0b780e2c5CAS |

Turner, S. P., Foden, J. D., Sandiford, M, and Bruce, D, 1993, Sm-Nd isotopic evidence for the provenance of sediments from the Adelaide Fold Belt and southeastern Australia with implications for episodic crustal addition: Geochimica et Cosmochimica Acta, 57, 1837–1856
Sm-Nd isotopic evidence for the provenance of sediments from the Adelaide Fold Belt and southeastern Australia with implications for episodic crustal addition:Crossref | GoogleScholarGoogle Scholar | 1:CAS:528:DyaK3sXktlWktb0%3D&md5=510be5da8bcd931876c3fe8f905c646fCAS |

van Otterloo, J., 2011, Newer Volcanics Map. Available at http://vhub.org/resources/845 (accessed 25 May 2012).

White, M. R., 1996, Subdivision of the Gambier Limestone: MESA Journal, 1, 35–39

Woodhead, J., Hergt, J., Sandiford, M., and Johnson, W., 2010, The big crunch: physical and chemical expressions of arc/continent collision in the Western Bismarck arc: Journal of Volcanology and Geothermal Research, 190, 11–24
The big crunch: physical and chemical expressions of arc/continent collision in the Western Bismarck arc:Crossref | GoogleScholarGoogle Scholar | 1:CAS:528:DC%2BC3cXhs1Gksr4%3D&md5=15f5904d2041fe254744522b7fd47de6CAS |