Preservation of thermal signature of elevated syn-rift heat flow during multiphase extension: a case study from the Duntroon Sub-basin, Great Australian Bight
Simon Holford A * , Ian Duddy B , Paul Green B , Nick Schofield C , Richard Hillis A and Martyn Stoker AA School of Physics, Chemistry and Earth Sciences, University of Adelaide, SA, Australia.
B Geotrack International, Vic., Australia.
C School of Geosciences, University of Aberdeen, Scotland, UK.
The APPEA Journal 63 S247-S250 https://doi.org/10.1071/AJ22060
Accepted: 16 March 2023 Published: 11 May 2023
© 2023 The Author(s) (or their employer(s)). Published by CSIRO Publishing on behalf of APPEA.
Abstract
Quantifying the thermal histories of rift basins is important for evaluating their resource and CO2 storage potential because temperature controls hydrocarbon generation, and the diagenesis of reservoir rocks. However, in many rift basins, it is difficult to obtain evidence for elevated heat flow accompanying rifting, since paleotemperature data from drilled sections typically record heating related to post-rift burial. Here we integrate geochemical, geophysical and petrophysical data from the Duntroon Sub-basin, Great Australian Bight, that show how strain-migration during multiphase extension can preserve the signature of syn-rift elevated geothermal gradients. During the late Jurassic–early Cretaceous, rifting was focussed along ~ESE-striking normal fault systems in the northern part of the Duntroon Sub-basin. During the late Cretaceous, strain migrated to the southwest through the development of normal faults which accommodated the deposition of Upper Cretaceous strata. The Echidna-1 well was drilled into a basement high, in the footwall of a late Cretaceous fault system, penetrating ~2.5 km of Lower Cretaceous strata. Paleotemperature proxies define an early Cretaceous paleogeothermal gradient of ~60°C km−1, substantially higher than the present-day gradient. Our results indicate that preserved Lower Cretaceous strata were more deeply buried by ~1 km of additional section, which was likely eroded during an episode of mid-Cretaceous exhumation associated with the migrating locus of rifting; this enabled the preservation of thermal signature of elevated syn-rift heat flow. Similar evidence is also observed in the Otway Basin, demonstrating the regional extent of elevated syn-rift heat flow along the southern Australian margin.
Keywords: exhumation, extension, Great Australian Bight, heat flow, normal faulting, reservoirs, rifting, thermochronology.
Professor Simon Holford is South Australian State Chair of Petroleum Geoscience in the Discipline of Earth Sciences, University of Adelaide. Simon has published ~130 papers on the prospectivity and tectonics of rifted margins, petroleum geomechanics and magmatism in basins. Simon has a PhD from the University of Birmingham and a BSc (Hons) from Keele University. Simon has won multiple awards, including Best Paper prizes at APPEA 2012 and AEGC 2019, Best Extended Abstract at APPEA 2021 and the Geological Society of Australia’s Walter Howchin and ES Hills medals. |
Ian Duddy is a founding Director of Geotrack International Pty Ltd, specialist consultants in thermal history reconstruction for basin modelling. He obtained BSc (Hons) and PhD degrees in Geology from the University of Melbourne and has been involved in researching the thermal evolution of sedimentary basins since 1975. He is a member of PESA and the Geological Society of Australia, which awarded him the Selwyn Medal for significant contributions to Victorian Geology in 2014. |
Paul Green is recently retired from his position as Technical Director of Geotrack International, a private company specialising in thermal history reconstruction in sedimentary basins, and its application to hydrocarbon exploration. He has a PhD from the University of Birmingham, and is the author of over 100 published papers in peer-reviewed journals on fission track analysis and related topics. |
Professor Nick Schofield is Chair in Igneous and Petroleum Geology at the University of Aberdeen. He gained his undergraduate degree in Geology from the University of Edinburgh, before undertaking a PhD at the University of Birmingham investigating the emplacement of sill intrusions. He has worked and published extensively on intrusive and extrusive volcanism within sedimentary basins globally and works closely with the petroleum industry on igneous-related aspects of the subsurface. |
Richard Hillis is Non-Executive Chair of Investigator Resources and Emeritus Professor at the University of Adelaide. He graduated with a BSc (Hons) from Imperial College, and a PhD from the University of Edinburgh. From 2010 to 2018 he was CEO of the Deep Exploration Technologies Cooperative Research Centre (DET CRC) and from 2019 to 2021 Pro Vice-Chancellor (Research Performance) at the University of Adelaide. Richard is a Fellow of ATSE and was South Australian Scientist of the Year 2018. |
Martyn Stoker is a Visiting Research Fellow at the School of Physics, Chemistry and Earth Sciences at the University of Adelaide. He graduated with a BSc (Hons) in Geology from the University of Leicester in 1977 and then a PhD from the University of Liverpool in 1980. Between 1981 and 2016 he worked in the Marine Science Programme of the British Geological Survey in Edinburgh, Scotland, and continues to publish on the tectonostratigraphic development of passive continental margins. |
References
Allen PA, Allen JR (2013) ‘Basin Analysis: Principles and Application to Petroleum Play Assessment.’ (John Wiley & Sons)Bradshaw BE, Rollet N, Totterdell JM, Borissova I (2003) ‘A Revised Structural Framework for Frontier Basins on the Southern and Southwestern Australian Continental Margin.’ 89 p. (Geoscience Australia Record 2003/03)
Duddy IR (1997) Focussing exploration in the Otway Basin: understanding timing of source rock maturation. The APPEA Journal 37, 178–191.
| Focussing exploration in the Otway Basin: understanding timing of source rock maturation.Crossref | GoogleScholarGoogle Scholar |
Hantschel T, Kauerauf AI (2009) ‘Fundamentals of Basin and Petroleum Systems Modeling.’ (Springer Science & Business Media)
Holford SP, Hillis RR, Duddy IR, Green PF, Tassone DR, Stoker MS (2011) Paleothermal and seismic constraints on late Miocene–Pliocene uplift and deformation in the Torquay Sub-basin, southern Australian margin. Australian Journal of Earth Sciences 58, 543–562.
| Paleothermal and seismic constraints on late Miocene–Pliocene uplift and deformation in the Torquay Sub-basin, southern Australian margin.Crossref | GoogleScholarGoogle Scholar |
MacDonald J, Backé G, King R, Holford S, Hillis R (2012) Geomechanical modelling of fault reactivation in the Ceduna Sub-basin, Bight Basin, Australia. Geological Society, London, Special Publications 367, 71–89.
| Geomechanical modelling of fault reactivation in the Ceduna Sub-basin, Bight Basin, Australia.Crossref | GoogleScholarGoogle Scholar |
McKenzie D (1978) Some remarks on the development of sedimentary basins. Earth and Planetary Science Letters 40, 25–32.
| Some remarks on the development of sedimentary basins.Crossref | GoogleScholarGoogle Scholar |
Messent BEJ (1998) ‘Great Australian Bight: Well Audit.’ (AGSO Record 1998/37)
Reynolds P, Holford S, Schofield N, Ross A (2022) 3D seismic reflection constraints on the emplacement of mafic laccoliths and their role in shallow crustal magma transport: a case study from the Ceduna Sub-basin, Great Australian Bight. Marine and Petroleum Geology 135, 105419
| 3D seismic reflection constraints on the emplacement of mafic laccoliths and their role in shallow crustal magma transport: a case study from the Ceduna Sub-basin, Great Australian Bight.Crossref | GoogleScholarGoogle Scholar |
Smith MA, Donaldson IF (1995) The hydrocarbon potential of the Duntroon Basin. The APPEA Journal 35, 203–219.
| The hydrocarbon potential of the Duntroon Basin.Crossref | GoogleScholarGoogle Scholar |
Struckmeyer HIM, Totterdell JM, Blevin JE, Logan GA, Boreham CJ, Deighton I, Krassay AA, Bradshaw MT (2001) Character, maturity and distribution of potential Cretaceous oil source rocks in the Ceduna Sub-basin, Bight Basin, Great Australian Bight. In ‘Eastern Australian Basins Symposium I’. pp. 543–552. (Petroleum Exploration Society of Australia)
Tassone DR, Holford SP, Duddy IR, Green PF, Hillis RR (2014) Quantifying Cretaceous–Cenozoic exhumation in the Otway Basin, southeastern Australia, using sonic transit time data: implications for conventional and unconventional hydrocarbon prospectivity. AAPG Bulletin 98, 67–117.
| Quantifying Cretaceous–Cenozoic exhumation in the Otway Basin, southeastern Australia, using sonic transit time data: implications for conventional and unconventional hydrocarbon prospectivity.Crossref | GoogleScholarGoogle Scholar |
Totterdell JM, Bradshaw BE (2004) The structural framework and tectonic evolution of the Bight Basin. In ‘Eastern Australian Basins Symposium II’. pp. 41–61. (Petroleum Exploration Society of Australia)