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The detection and characterization of domains of intersecting fractures are important goals in several disciplines of current interest, including exploration and production of unconventional reservoirs, nuclear waste storage, CO2 sequestration, and groundwater hydrology, among others. The objective of this study is to propose a theoretical framework for quantifying the effects of fracture intersections on the frequency-dependent elastic properties of fluid-saturated porous and fractured rocks. Three characteristic frequency regimes for fluid pressure communication are identified. In the low frequency limit, fractures are in full pressure communication with the embedding porous matrix and with other fractures. Conversely, in the high frequency limit, fractures are hydraulically isolated from the matrix and from other fractures. At intermediate frequencies, fractures are hydraulically isolated from the matrix porosity, but can be in hydraulic communication with each other, depending on whether fracture sets are intersecting. For each frequency regime the effective stiffness coefficients are derived using the linear-slip theory and anisotropic Gassmann equations. Explicit mathematical expressions for the two characteristic frequencies that separate the three frequency regimes are also determined. The theoretical predictions are then applied to two synthetic 2D samples each containing two orthogonal fracture sets, one with and the other without intersections. The resulting stiffness coefficients, Thomsen-style anisotropy parameters as well as the transition frequencies show good agreement with corresponding numerical simulations. The theoretical results are applicable not only to 2D but also to 3D fracture systems and are amenable to being employed in inversion schemes designed to characterize fracture systems.
Bio:
Boris Gurevich has PhD in Geophysics from Institute of Geosystems, Moscow (1988). His career includes research positions at Institute of Geosystems, Moscow from 1981 to 1994 and at the Geophysical Institute of Israel in 1995-2000. Since 2001 he has been a Professor of Geophysics at Curtin University and advisor to CSIRO Energy (Perth, Western Australia), where he has had both research and management duties as an academic department chair. His main interests are in rock physics, poroelasticity, seismic theory, modelling, imaging and 4D.