Deformation band populations in fault damage zone—impact on fluid flow

Fault damage zones in highly porous reservoirs are dominated by deformation bands that generally have permeability-reducing properties. Due to an absence of sufficiently detailed measurements and the irregular distribution of deformation bands, a statistical approach is applied to study their influe...

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Bibliographic Details
Published in:Computational geosciences 2010-03, Vol.14 (2), p.231-248
Main Authors: Kolyukhin, Dmitry, Schueller, Sylvie, Espedal, Magne S., Fossen, Haakon
Format: Article
Language:English
Subjects:
Earth and Environmental Science
Earth Sciences
Flow characteristics
Fluid flow
Geophysics
Geotechnical Engineering & Applied Earth Sciences
Hydrogeology
Mathematical Modeling and Industrial Mathematics
Original Paper
Permeability
Seismology
Soil Science & Conservation
Stochastic models
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Summary:Fault damage zones in highly porous reservoirs are dominated by deformation bands that generally have permeability-reducing properties. Due to an absence of sufficiently detailed measurements and the irregular distribution of deformation bands, a statistical approach is applied to study their influence on flow. A stochastic model of their distribution is constructed, and band density, distribution, orientation, and flow properties are chosen based on available field observations. The sensitivity of these different parameters on the upscaled flow is analyzed. The influence of a heterogeneous permeability distribution was also studied by assuming the presence of high permeability holes within bands. The fragmentation and position of these holes affect significantly the block-effective permeability. Results of local upscaling with a diagonal and full upscaled permeability tensor are compared, and qualitatively similar results for the flow characteristics are obtained. Further, the procedure of iterative local–global upscaling is applied to the problem.
ISSN:1420-0597
1573-1499
DOI:10.1007/s10596-009-9148-8