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Abstract

AAPG Bulletin, V. 93, No. 12 (December 2009), P. 16911704.

Copyright copy2009. The American Association of Petroleum Geologists. All rights reserved.

DOI:10.1306/06010908130

Three-dimensional kinematic modeling of reversible fault and fold development

Natacha Gibergues,1 Muriel Thibaut,2 Jean-Pierre Gratier3

1Institut Francais du Petrole, Av. de Bois Preau, BP 311, Rueil-Malmaison 92506, France; [email protected]
2Institut Francais du Petrole, Av. de Bois Preau, BP 311, Rueil-Malmaison 92506, France; [email protected]
3Laboratoire de Geophysique Interne et Tectonophysique, CNRS-Observatoire, Universite Joseph Fourier, Geosciences, BP 53X, Grenoble 38041, France; [email protected]

ABSTRACT

In the current context of continuous supply of energy, the discovery and development of new prospects will rely on our ability to detect reserves in deeper and structurally more complex formations. These exploration areas stretch the capabilities of currently available three-dimensional (3-D) exploration software, which cannot accommodate a realistic geometrical description of present-day geological structures and the tectonic deformation steps. Correctly handling the kinematics of structural deformation and evaluating the pressure regime and temperature history at the scale of exploration will remain as challenges for several years to come. In this article, we focus on geometric aspects using a reversible kinematic approach to deform and restore faulted and folded structures. Kinematic modeling is a good alternative to the complexity of a mechanical approach and is sufficiently representative of the natural processes involved (sedimentation, erosion, and compaction). Its reversibility ensures that the basin parameters need to be defined only once for both the restoration and the deformation steps. The model describes the incremental development of the basin in space and time. It is based on a hexahedral discretization process that is fully adapted and appropriate for thermal and fluid transfer. Different deformation modes (flexural slip and vertical shear) are mixed to integrate natural deformation more effectively. The algorithm is validated using different geological examples of growing complexity up to curved normal and thrust faults. The approach offers various prospects for improvement, integrating both kinematic and mechanical constraints. Considering the challenges that the industry needs to overcome in future exploration, the results of this approach are very encouraging and can be considered as a solution for solving the structural part of 3-D basin modeling in complex areas.

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