Integrated fracture prediction using sequence stratigraphy within a carbonate fault damage zone, Texas, USA

Integrated fracture prediction using sequence stratigraphy within a carbonate fault damage zone, Texas, USA

Fracture deformation intensity is heterogeneous as a result of the interplay between the stratigraphic architecture and the degree of faulting. Prediction of the distribution of fractures requires careful consideration of the sequence stratigraphic framework in concert with the structural deformatio...

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Bibliographic Details
Published in:Journal of structural geology Vol. 32; no. 9; pp. 1363 - 1374
Main Authors: Zahm, Christopher K., Zahm, Laura C., Bellian, Jerome A.
Format: Journal Article
Language:English
Published: Elsevier Ltd 01-09-2010
Subjects:
Carbonate
Fault damage zone
Fractures
HST
Sequence stratigraphy
TST
HST
Sequence stratigraphy
Carbonate
Fractures
TST
Fault damage zone
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Summary:Fracture deformation intensity is heterogeneous as a result of the interplay between the stratigraphic architecture and the degree of faulting. Prediction of the distribution of fractures requires careful consideration of the sequence stratigraphic framework in concert with the structural deformation process. Deformation intensity was found to vary by facies that were divided into distinct mechanical units and characterized within a sequence stratigraphic framework. Deformation was found to be more intensely developed within the transgressive systems tract (TST) versus the highstand systems tract (HST). In the HST, facies observed in the outcrop from this study had less mud, thicker cycles, and higher unconfined strength (average of 57 MPa for non-argillaceous facies). In contrast, the TST cycle sets have a higher argillaceous component and cycles are thinner. The facies have a higher mud content and lower unconfined strength (average of 49 MPa for non-argillaceous facies). The reduction in rock strength is compounded by thinner beds and increased frequency of argillaceous wackestone beds. The TST facies also affect the geometry of secondary faults, creating asperities along the fault plane that cause further deformation. Overall, the integration of facies, rock strength and mud content within a sequence stratigraphic framework provides an improved methodology for prediction of deformation within a carbonate fault damage zone.
ISSN:0191-8141
1873-1201
DOI:10.1016/j.jsg.2009.05.012