Permeability Modeling in Porous Media: Setting Archie and Carman-Kozeny Right

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Abstract Archie empirical law is the basis of quantitative Petrophysics. The physical significance of this law is not well understood. This issue involves substantial uncertainty in oil in place. Similarly, Carman-Kozeny (C-K) relationship is source of several permeability models. C-K is derived from Poiseuille equation, applicable in laminar viscous flow in straight non-communicating uniform tubes. Neither Poiseuille nor C-K formulae consider convective/inertial accelerations caused by changes in either cross section or flow direction. Implications include sizeable limitations in permeability modeling. In this paper, appropriate hydrodynamic and electrical models are created using fluid mechanics analytical methods. The models delineate the velocity and electrical potentials, streamlines and controls, represented by C-K and Archie equations. This approach theoretically verifies both relations and demonstrates that: Fluid circulation and permeability are optimally modeled invoking superposition of viscous and inertial regimes in nozzles, throats, diffusers, pipe networks, and arrays of solid particles. These hydraulic components, once assembled, emulate porous media well. Changes in fluid and electric flow direction are characterized by the flow around a corner solution of Laplace differential equation. The solution precisely defines rock frame, conductive phase, and hydraulic tortuosities, enabling direct ties to pore geometry. This facilitates permeability calculations utilizing the "perfect permeability transform" procedure. Several experiments/examples are discussed to show validity. Some conclusions and technical contributions/applications are: Electric measurements can predict hydraulic and petrophysical rock properties. Cementation exponent can be continuously computed employing acoustic tools and rock physics principles. Saturation exponent can be geometrically related to wettability and saturation using pore-scale modeling. A quantitative rock catalog can be implemented applying practical rock type definitions. Supported by these concepts, synthetic production logs can be generated to anticipate well performance, and to effectively assist in history matching. Archie law ceases being merely empirical. We gain a thorough physical understanding of its power law (fractal?) behavior. Rock responses can now be clearly explained and evaluated.