Effective Conductivity Modeling of a Fluid Saturated Porous Rock
Author(s)
Zhan, Xin; Toksoz, M. Nafi
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Massachusetts Institute of Technology. Earth Resources Laboratory
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The microstructure of a porous medium and physical characteristics of the solid and the fluids that occupy
the pore space determine the macroscopic transport properties of the medium. The computation of
macroscopic properties from the rock microtomography is becoming an increasingly studied topic. The
transport properties are especially difficult to determine at the microscopic scale. In this paper, we will
focus on modeling the electric conductivity from the X-ray CT microtomograhpy of a 1mm3 Fontainbleau
Sandstone sample. To accomplish this, we modified the finite difference Laplace solver developed at NIST
(National Institute of Standards and Technology, Gaithersburg, MD 20899-8621, U.S.A). Our modified
finite difference code can calculate the effective conductivity of random materials with different levels of
conductivity contrasts. The effective conductivity and the current density distribution of gas, oil and
different salinity brine saturated Fontainbleau Sandstone are calculated using a two-phase model. When we
compare our numerical results with experimental results from previous studies, the numerically resolved
conductivity is almost 100% lower than the experimental data. This is the case for all of the previous work
on the numerical computation of electric conductivity from digital images of rocks. Our explanation for this
large discrepancy is due to the exclusion of the surface conductivity in the electric double layer (EDL) at
the rock-electrolyte interface. Thus, we develop a three phase conductivity model to include the surface
conductivity and determine the effective conductivity of the numerical grids containing the EDL from the
Waxman-Smits equation. By adding the surface conductivity into our numerical modeling, the calculated
conductivity from rock microtomography is much closer to the experimental data.
Date issued
2007-05-27Publisher
Massachusetts Institute of Technology. Earth Resources Laboratory
Series/Report no.
Earth Resources Laboratory Industry Consortia Annual Report;2007-11