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Geological Society, London, Special Publications; 2007; v. 270; p. 1-21;
DOI: 10.1144/GSL.SP.2007.270.01.01
© 2007 Geological Society of London

Outcrop studies

Structural and stratigraphic controls on fold-related fracturing in the Zagros Mountains, Iran: implications for reservoir development

Ben J. Stephenson1,3, Anton Koopman1, Heiko Hillgartner1, Harry McQuillan2, Stephen Bourne1, Jon J. Noad1 & Keith Rawnsley1

1 Shell E&P International Centre, Carbonate Development team, Kessler Park 1, 2288GS Rijswijk-ZH, The Netherlands
2 Zagros Orchard, R.D. 1, Upper Moutere, Nelson, New Zealand

New observations of fracture corridors > 150 m tall and planes of bedding-parallel slip are integrated with sedimentological descriptions of the Asmari Formation to understand the main controls on the development of fractures in the Zagros Mountains of Iran. In the Kuh-e Pahn, fold-related fracture corridors are axis-parallel (NW-SE) and occur in the crest of the anticline. They form by neutral surface folding, but at a critical dip of the beds (c. 15°), bedding-parallel slip by flexural slip folding is the predominant mechanism. This relationship is substantiated by curvature calculations. Crestal fractures have a large vertical extent in mechanical unit B (> 150 m), primarily due to the lithological homogeneity of massive packstones within the Asmari Formation. Northerly and easterly trending fracture corridors, interpreted from satellite imagery, are spatially unrelated to the detachment folding of the cover series, but represent the distributed effect of deep-seated basement reactivation related to fault movement. These trends define high production zones in the nearby Gachsaran super giant oilfield. Observations from an adjacent eroded box fold, the Kuh-e Mish, with steeper dipping limbs (60°), revealed a contrast in the style of deformation, and we interpret these folds to represent different stages in box fold evolution.





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