1887
24th International Geophysical Conference and Exhibition – Geophysics and Geology Together for Discovery
  • ISSN: 2202-0586
  • E-ISSN:

Abstract

The present-day stress field is important for a range of earth science disciplines including petroleum and geothermal geomechanics, mine safety, neotectonics and seismic hazard assessment. So far, many studies have been carried out to understand the state of stress in different parts of the world and the results reveal that the contemporary tectonic stress field can range from being uniform over large areas (100s-1000s of kilometres) to being highly varied over short distances (10s-100s of meters) due to interaction of different parameters. One of the most well-known examples of a heterogeneous stress pattern is observed in the Australian continent, which displays a wide range of stress orientations from province to province that, unlike all other major plates, are not aligned with absolute plate motion.

The Australian Stress Map (ASM) project was started in 1996 to compile a public data set of maximum horizontal present-day tectonic stress information to determine and understand the state of stress in the Australian crust. The early phases of the ASM revealed that plate boundary forces provide the first-order control on the present-day stress pattern. However, all models of the stress field have failed to replicate the stress pattern in Eastern, and particularly north-eastern, Australia. The ASM project commenced again in 2012 with a primary aim of building up the database in Eastern Australia, such as new hydrocarbon provinces, and to help better establish the controls on the Australian stress field at scales ranging from tectonic plate down to individual fields and wells. To date, we have interpreted more than 400 borehole image logs in coal seam gas, mineral and conventional petroleum wells. The results show that local sources of stress (i.e. second and third orders) play a key role in the stress pattern of Australia which is an important issue for geothermal and unconventional exploration and production.

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2015-12-01
2026-01-22

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References

  1. Bell, J. S. 1996. Petro Geoscience 2, In situ stresses in sedimentary rocks (Part 2): Applications of stress measurments, Geoscience Canada, 23, 135-153
  2. Bell, J. S., 2006, In-situ stress and coal bed methane potential in west Canada: Bulletin of Canadian Petroleum Geology, 54, 197-220.
  3. Clark, D. McPherson, A. and Van Dissen, R. 2012, Long-term behaviour of Australian stable continental region (SCR) faults, Tectonophysics, 566-567, 1-30.
  4. Flottmann, T., Brooke-Barnett, S., Trubshaw, R., Naidu, S., Kirk-Burnnand, E., Pijush, P., Busetti, S., Hennings, P., 2013, Influence of in-situ stresses on fractures stimulations in the Surat Basin, Southeast Qyeensland, SPE Unconventional Resources Conference and Exhibition-Asia Pacific, 11-13 November, Brisbane, Australia. SPE-167064-MS.
  5. Heidbach, O., Tingay, M.R.P., Barth, A., Reinecker, J., KurfeP, D., Miiller, B., 2010, Global crustal stress pattern based on the World Stress Map database release 2008, Tectonophysics, 482, 3-15.
  6. Hillis, R.R., 2000, Pore pressure/stress coupling and its implications for seismicity, Exploration Geophysics, 31, 448454.
  7. Hillis, R. R. Meyer, J. J. and Reynolds, S. D. 1998, the Australian stress map, Exploration Geophysics, 29, 420-427.
  8. Hillis, R. R. and Reynolds, S. D. 2003, In situ stress field of Australia, In: Evolution and Dynamics of the Australian Plate (edited by Hillis, R. R. and Muller, R. D.) Geological Society of Australia Special Publication 22 and Geological Society of America Special Paper, 372, 49-60.
  9. Hillis, R. R. Sandiford, M. Reynolds, S. D. and Quigley, M. C. 2008, Present-day stresses, seismicity and Neogene-to-Recent tectonics of Australia’s ‘passive’ margins: intraplate deformation controlled by plate boundary forces, In: Johnson, H. Dore, A. G. Gatliff, R. W. Holdsworth, R. Lundin, E. R. and Ritchie, J. D. (Eds.), The Nature and Origin of Compression in Passive Margins, Geological Society of London Special Publication, 306, 71-90.
  10. Reynolds, S. D. Coblentz, D. D. and Hillis, R. R. 2003, Influences of plate-boundary forces on the regional intraplate stress field of continental Australia, In: Evolution and Dynamics of the Australian Plate (edited by Hillis, R. R. and Muller, R. D.) Geological Society of Australia Special Publication 22 and Geological Society of America Special Publication, 372, 59-70.
  11. Richardson, R.M., 1992, Ridge forces, absolute plate motions, and the intraplate stress field, Journal of Geophysical Research, 97, 11739-11748.
  12. Sandiford, M. Wallace, M. and Coblentz, D. 2004, Origin of the in situ stress field in southeastern Australia, Basin Research, 16, 325-338.
  13. Tingay, M. Muller, B. Reinecker, J. Heidbach, O. Wenzel, F. Flecknstein P. 2005, Understanding tectonic stress in the oil patch: the World Stress Map Project, The Leading Edge, 24 (12), 1276-1282.
  14. Zoback, M.D., 2007, Reservoir Geomechanics, Cambridge University Press, New York (449 pp.).
  15. Zoback, M.L. 1992, First- and second-order patterns of stress in the lithosphere: the world stress map project, Journal of Geophysical Research, 97 (B8), 11703-11728.
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  • Article Type: Research Article
Keyword(s): Australian stress map; present-day stress; stress pattern of Australia; stress rotation

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