--> Abstract: 4-D Analysis of Extensional Fault Systems in Rift Basins, Ken McClay, by Ken McClay; #90912 (2000).

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Abstract: 4-D Analysis of Extensional Fault Systems in Rift Basins

MCCLAY, KEN, ARCO Professor of Structural Geology, Royal Holloway, University of London, UK 

The 4-D evolution of extensional fault systems in sedimentary basins and in particular rift systems has been investigated using scaled sandbox analog models. Sandbox models have proved to be a powerful and graphic tool in developing an understanding of the 4-D geometric and kinematic evolution of extensional fault systems. The model results have been compared with natural examples of extensional fault systems at both outcrop and seismic scales. Many rift basins and passive margins contain major hydrocarbon accumulations, and an understanding of the geometric and kinematic evolution of the extensional fault systems that control them is vital for successful exploration and production.

Analog models of rift basins have been constructed using dry, cohesionless, fine-grained quartz sand to simulate the brittle deformation of sedimentary rocks in the upper 10 km of the crust. Extensional deformation in the models was controlled by the orientation and geometry of a zone of stretching at the base of the model, either a rubber sheet or a layer of viscous silicone polymer. Models have been run for orthogonal, oblique, offset, and stepped rift systems. The top surfaces of the models were recorded by time-lapse photography and completed models were serially sectioned for detailed analysis.

In orthogonal and oblique rift models stretching of the sandpack above a zone of ductile deformation at the base of the models produced model rift basins constrained by long, initially segmented border fault systems parallel to the underlying zone of basal stretching, together with subbasins within the rift formed by domino-style intrarift faults. For the orthogonal (90°) and for oblique rift models where the zone of stretching (rift axis) was up to 15° to the extension direction, the intrarift faults were at high angles to the extension direction. For oblique rift models where the rift axis was 45° or less to the extension direction the intrarift faults were rotated subparallel to the rift axis. Offset and stepped rift models were characterized by highly segmented border faults and offset subbasins within the rift without the development of strike-slip or oblique-slip transfer faults. For the oblique, offset, and stepped rift models, both the intrarift and rift border faults are highly segmented with individual offsets of like-dipping, domino-style, extensional faults forming characteristic relay ramp structures. Offset, oppositely dipping extensional faults form interlocking fault arrays--transfer zones. Along-strike displacement transfer within the rift between segmented and offset subbasins is accommodated by "soft-linked" accommodation zones characterized by interlocking arrays of conjugate extensional fault systems. The results of these analog model studies have permitted the construction of 4-D evolutionary extensional fault models that can be applied to natural fault systems in sedimentary basins.

The results of the analog models are compared and contrasted with natural examples of extensional fault systems from the Gulf of Suez and Red Sea, Egypt, from the Gulf of Aden, Yemen, from the North Sea, Indonesia, and Australia. These natural extensional fault systems show geometries, segmentation, and offset structures that are extremely similar to those developed in the analog models. 

See page 1064 of PDF.

AAPG Search and Discovery Article #90912©1999-2000 AAPG International Distinguished Lectures