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Abstract
Albertz, Markus, Christopher Beaumont, and Steven J. Ings,
DOI:10.1306/13231307M933417
Geodynamic Modeling of Sedimentation-induced Overpressure, Gravitational Spreading, and Deformation of Passive Margin Mobile Shale Basins
Markus Albertz,1 Christopher Beaumont,2 Steven J. Ings3
1Department of Oceanography, Dalhousie University, Halifax, Nova Scotia, Canada; present address: Exxon Mobil Upstream Research Company, Houston, Texas, U.S.A.
2Department of Oceanography, Dalhousie University, Halifax, Nova Scotia, Canada
3Department of Earth Sciences, Dalhousie University, Halifax, Nova Scotia, Canada
ACKNOWLEDGMENTS
This research was funded by an Atlantic Canada Opportunities Agency Atlantic Innovation Fund contract (PanAtlantic Petroleum Systems Consortium), by IBM, and by Shell International Exploration and Production Inc. M. Albertz acknowledges additional support from Natural Resources Canada and the German Research Foundation. C. Beaumont was supported by the Canada Research Chair in Geodynamics. S. J. Ings was supported by a Natural Sciences and Engineering Research Council of Canada, Canada Graduate Scholarship. The numerical finite element code was developed by Philippe Fullsack, and Bonny Lee assisted with the implementation of the parametric pore-fluid pressure model. We thank Philippe Fullsack, Sofie Gradmann, Glen Stockmal, Richard Wiener, and Chris Connors for helpful comments and Dan Schultz-Ela for a technical review.
ABSTRACT
We investigate the differential loading and pore-fluid pressure required for failure and subsequent prolonged gravitational spreading of passive margin shale basins using two-dimensional analytical limit analysis and plane-strain finite element modeling. The limit analysis, supported by the models, indicates that narrow margins (slope regions that are approximately 50 to 100 km [31 to 62 mi] wide) require pore-fluid pressures that are 80–94% of the overburden weight for failure to occur, whereas for wider margins (400 km [250 mi] wide) like the Niger Delta, the corresponding values are 95–99%; these ranges depend on the intrinsic strength of sediments.
In the large deformation models, gravitational spreading in response to sedimentation-induced overpressure caused by delta progradation is investigated. Shale is modeled as a viscoplastic Bingham fluid that is frictional-plastic below yield and has a yield criterion that depends on the effective pressure (mean stress minus pore-fluid pressure). The velocity of the postyield flow of the shale is limited by the viscosity of the Bingham fluid, chosen for this study to be 1018 Pas. Pore-fluid pressure is predicted parametrically to be proportional to the local sedimentation rate during progradation, where the proportionality constant, kc, depends inversely on the hydraulic conductivity. Varying the sediment progradation rate, the depth of onset of excess pore pressure, and kc produces model deformation patterns consistent with seaward-directed squeeze-type flow of overpressured shale (Poiseuille flow) or wholesale seaward motion of the shale and overburden (Couette flow), depending on the overall mobility of the model.
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