Please use this identifier to cite or link to this item: http://hdl.handle.net/2440/81596
Type: Journal article
Title: Quantifying fault reactivation risk in the western Gippsland basin using geomechanical modelling
Author: Swierczek, E.
Zhen-dong, C.
Holford, S.
Backe, G.
King, R.
Mitchell, A.
Citation: APPEA Journal, 2013; 53:255-272
Publisher: Australian Petroleum Production and Exploration Association
Issue Date: 2013
ISSN: 1326-4966
Department: Faculty of Engineering, Computer & Mathematical Sciences
Organisation: Institute for Mineral and Energy Resources (IMER)
Statement of
Responsibility: 
E. Swierczek, C. Zhen-dong, S. Holford, G. Backé, R. King and A. Mitchel
Abstract: The Rosedale Fault System (RFS) bounds the northern margin of the Gippsland Basin on the Southern Australian Margin. It comprises an anastomosing system of large, Cretaceous-age normal faults that have been variably reactivated during mid Eocene–Recent inversion. A number of large oil and gas fields are located in anticlinal traps associated with the RFS, and in the future these fields may be considered as potential storage sites for captured CO2. Given the evidence for geologically recent fault reactivation along the RFS, it is thus necessary to evaluate the potential impacts of CO2 injection on fault stability. The analysis and interpretation of 3D seismic data allowed the authors to create a detailed structural model of the western section of the RFS. Petroleum geomechanical data indicates that the in-situ stress in this region is characterised by hybrid strike-slip to reverse faulting conditions where SHmax (40.5 MPa/km) > SV (21 MPa/km) ~ Shmin (20 MPa/km). The authors performed geomechanical modelling to assess the likelihood of fault reactivation assuming that both strike-slip and reverse-stress faulting regimes exist in the study area. The authors’ results indicate that the northwest to southeast and east-northeast to west-southwest trending segments of the RFS are presently at moderate and high risks of reactivation. The authors’ results highlight the importance of fault surface geometry in influencing fault reactivation potential, and show that detailed structural models of potential storage sites must be developed to aid risk assessments before injection of CO2.
Keywords: Rosedale Fault System; Gippsland Basin; fault reactivation; fracture stability; slip stability; dilation tendency; fault modelling
Rights: © Springer-Verlag Berlin Heidelberg 2013
RMID: 0020137107
Description (link): http://www.appea.com.au/industry-in-depth/appea-submissions-and-reports/appea-journal/
Published version: http://www.appea.com.au/industry-in-depth/appea-submissions-and-reports/the-appea-journal/
Appears in Collections:Australian School of Petroleum publications

Files in This Item:
There are no files associated with this item.


Items in DSpace are protected by copyright, with all rights reserved, unless otherwise indicated.