Using network topology to constrain fracture network permeability

Rowan Hansberry; Simon Holford; Rosalind King; Natalie Debenham

doi:10.1080/22020586.2019.12073009

2nd Australasian Exploration Geoscience Conference: Data to Discovery

ISSN: 2202-0586
E-ISSN:

oa Using network topology to constrain fracture network permeability
Authors Rowan Hansberry^a, Simon Holford^b, Rosalind King^c and Natalie Debenham^d
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^a Department of Earth SciencesUniversity of Adelaide, [email protected] ^b Australian School of PetroleumUniversity of Adelaide, [email protected] ^c Department of Earth SciencesUniversity of Adelaide, [email protected] ^d Australian School of PetroleumUniversity of Adelaide, [email protected]
Publisher: Australian Society of Exploration Geophysicists
Source: ASEG Extended Abstracts, Volume 2019, Issue 2nd Australasian Exploration Geoscience Conference: Data to Discovery, Dec 2019, p. 1 - 4
DOI: https://doi.org/10.1080/22020586.2019.12073009
- Published online: 01 Dec 2019

Abstract

Summary

Predicting the interconnectivity and permeability of fractures at any scale remains a fundamental challenge in structural geology. Models which predict the likelihood of fracture opening based on their relation to the stress field can be applied at scales of 100s of metres to kilometres. Increasingly however, an understanding of how networks of the smallest-scale (sub-seismic to mm) natural fractures permit fluid flow in the subsurface appears key to predicting and exploiting these pathways. Here, we apply the nascent method of network topology to natural fracture networks to a fossilised fault damage zone in the Otway Basin. Network connectivity and the potential to percolate fluids has been shown to be directly related to the topology, and intensity of fracturing. This technique is relatively straightforward, provides a range of parameters to define various aspects of a fracture network (e.g. intensity, connectivity), and is independent of the scale and geometry of the structures of interest. We integrate this technique with traditional structural analysis to illustrate the scale of fracturing around a region-scale fault and constrain spatial variation in permeability associated with the fracture network. We also illustrate how elements of this technique might be applied to existing sub-surface data.

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2026-01-19

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References

Dershowitz, W. S., and Herda, H. H., Interpretation of fracture spacing and intensity, in Proceedings The 33th US Symposium on Rock Mechanics (USRMS)1992, American Rock Mechanics Association.
Nyberg, B., Nixon, C. W., and Sanderson, D. J., 2018, NetworkGT: A GIS tool for geometric and topological analysis of two-dimensional fracture networks: Geosphere.
Procter, A., and Sanderson, D. J., 2018, Spatial and layercontrolled variability in fracture networks: Journal of Structural Geology, v. 108, p. 52-65.
Sanderson, D. J., and Nixon, C. W., 2015, The use of topology in fracture network characterization: Journal of Structural Geology, v. 72, p. 55-66.
Sanderson, D. J., and Nixon, C. W., 2018, Topology, connectivity and percolation in fracture networks: Journal of Structural Geology, v. 115, p. 167-177.
Townend, J., and Zoback, M. D., 2000, How faulting keeps the crust strong: Geology, v. 28, no. 5, p. 399-402.
Debenham, N., King, R. C., & Holford, S. P. (2018a). The influence of a reverse-reactivated normal fault on natural fracture geometries and relative chronologies at Castle Cove, Otway Basin. Journal of Structural Geology, 112, 112-130.
Debenham, N., Farrell, N. J., Holford, S. P., King, R. C., & Healy, D. (2018b). The permeability structure of fault zones in sedimentary basins: a case study at the Castle Cove Fault, Otway Basin. The APPEA Journal, 58(2), 805-808.

/content/journals/10.1080/22020586.2019.12073009

Article Type: Research Article

Keyword(s): fault; fracture; permeability; structural; topology

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