Analysis of permeability controls: a new approach

C. A. Cade; I. J. Evans; S. L. Bryant

doi:10.1180/claymin.1994.029.4.08

Abstract

By modelling a range of rock-forming processes such as compaction and various styles of cementation, a new understanding of how they affect pore-system geometry, and hence permeability, has been gained. For example, almost identical permeability-porosity trends result from progressive compaction or grain overgrowth cementation in a clean sandstone, and these trends are curvilinear on the traditional log-linear plot. The steepening which defines the curve marks the onset of pore-throat blocking. Other cement styles, such as pore-filling carbonates or grain-rimming clays, show different porosity-permeability trends. This new understanding can be used predictively (predicting permeability from predictions of grain size and diagenetic style), or as a tool for identifying the important permeability controls in a set of field data. This latter application is presented and illustrated using data from a variety of sandstone types. This approach has important advantages over commonly used multivariate statistical analysis approaches. It can quickly provide a good understanding of what are (and are not) the important controls on permeability. It also provides a basis for more focused and meaningful statistical analysis to quantify these controls.

References

Beard, D.C. & Weyl, P.K. (1973) Influence of texture on porosity and permeability of unconsolidated sand. AAPG Bull. 57, 349–369.Google Scholar

Bloch, S. (1991) Empirical prediction of porosity and permeability in sandstones. AAPG Bull. 75, 1145–1160.Google Scholar

Bourbie, T. & Zinzsner, B. (1985) Hydraulic and acoustic properties as a function of porosity in Fontainebleau sandstone. J. Geophys. Res. 90, 11524–11532.Google Scholar

Bryant, S.L., Cade, C.A. & Mellor, D.W. (1993a) Permeability prediction from geological models. AAPG Bull. 77, 1338–1350.Google Scholar

Bryant, S.L., Mellor, D.W. & Cade, C.A. (1993b) Physically representative network models of transport in porous media. Al ChE J. 39, 387–396.Google Scholar

Carman, P.C. (1937) Fluid flow through granular beds. Trans. Inst. Chem. Eng. 15, 150–166.Google Scholar

Cayeux, L. (1929) Les roches sedimentaires de France. Roches siliceuses. Mem. Min. Travaux Publics, Paris, 48-49.Google Scholar

Dutton, S.P. & Diggs, T.N. (1992) Evolution of porosity and permeability in the Lower Cretaceous Travis Peak Formation, East Texas. AAPG Bull. 76, 252–269.Google Scholar

Ehrenserg, S.N. (1990) Relationship between diagenesis and reservoir quality in sandstones of the Garn Formation, Haltenbanken, Mid-Norwegian Continental Shelf. AAPG Bull. 74, 1538–1558.Google Scholar

Ehrlich, R., Etms, E.I., Brumfield, D., Yuan, L.P. & Crabtree, S.J. (1991) Petrography and reservoir physics III: Physical models for permeability and formation factor. AAPG Bull. 75, 1579–1592.Google Scholar

Ethier, V.G. & King, H.R. (1991) Reservoir quality evaluation from visual attributes on rock surfaces: methods of estimation and classification from drill cuttings or cores. Bull. Can. Petrol. Geol. 39, 233–251.Google Scholar

Finney, J. (1970) Random packings and the structure of simple Liquids, I. The geometry of random close packing. Proc. Roy. Soc. 319A, 479.Google Scholar

Crossref Citations

This article has been cited by the following publications. This list is generated based on data provided by Crossref.

Bryant, Steven and Pallatt, Nadia 1996. Predicting formation factor and resistivity index in simple sandstones. Journal of Petroleum Science and Engineering, Vol. 15, Issue. 2-4, p. 169.

Ecker, Christine Dvorkin, Jack and Nur, Amos 1996. Sediments with gas hydrates: Internal structure from seismic AVO. p. 1767.

Worden, R. H. Mayall, M. J. and Evans, I. J. 1997. Predicting reservoir quality during exploration: lithic grains, porosity and permeability in Tertiary clastic rocks of the South China Sea basin. Geological Society, London, Special Publications, Vol. 126, Issue. 1, p. 107.

Leveille, Gregory P. Primmer, Tim J. Dudley, Graham Ellis, David and Allinson, Gareth J. 1997. Diagenetic controls on reservoir quality in Permian Rotliegendes sandstones, Jupiter Fields area, southern North Sea. Geological Society, London, Special Publications, Vol. 123, Issue. 1, p. 105.

Worden, R. H. 1998. Dolomite cement distribution in a sandstone from core and wireline data: the Triassic fluvial Chaunoy Formation, Paris Basin. Geological Society, London, Special Publications, Vol. 136, Issue. 1, p. 197.

Kainourgiakis, M.E. Kikkinides, E.S. Steriotis, Th.A. Stubos, A.K. Tzevelekos, K.P. and Kanellopoulos, N.K. 2000. Structural and Transport Properties of Alumina Porous Membranes from Process-Based and Statistical Reconstruction Techniques. Journal of Colloid and Interface Science, Vol. 231, Issue. 1, p. 158.

Jennings, James W. and Lucia, F. Jerry 2001. Predicting Permeability From Well Logs in Carbonates With a Link to Geology for Interwell Permeability Mapping.

Jin, Guodong Patzek, Tad W. and Silin, Dmitry B. 2003. Physics-based Reconstruction of Sedimentary Rocks.

Jennings, James W. and Lucia, F. Jerry 2003. Predicting Permeability From Well Logs in Carbonates With a Link to Geology for Interwell Permeability Mapping. SPE Reservoir Evaluation & Engineering, Vol. 6, Issue. 04, p. 215.

Schmid, S Worden, R.H and Fisher, Q.J 2004. Diagenesis and reservoir quality of the Sherwood Sandstone (Triassic), Corrib Field, Slyne Basin, west of Ireland. Marine and Petroleum Geology, Vol. 21, Issue. 3, p. 299.

Gluyas, J. 2005. Encyclopedia of Geology. p. 141.

Slobozhanin, Lev A. Alexander, J. Iwan D. Collicott, Steven H. and Gonzalez, S. Roberto 2006. Capillary pressure of a liquid in a layer of close-packed uniform spheres. Physics of Fluids, Vol. 18, Issue. 8,

McKinley, Jennifer M. Warke, Patricia Lloyd, Christopher. D. Ruffell, Alastair H. and Smith, Bernard J. 2006. Geostatistical analysis in weathering studies: case study for Stanton Moor building sandstone. Earth Surface Processes and Landforms, Vol. 31, Issue. 8, p. 950.

Lee, Clement W. B. Budman, Hector M. and Pritzker, Mark D. 2006. Simulation and Optimization of the Continuous Oriented Strand Board Pressing Process. Industrial & Engineering Chemistry Research, Vol. 45, Issue. 6, p. 1974.

Worden, Richard H. 2006. Dawsonite cement in the Triassic Lam Formation, Shabwa Basin, Yemen: A natural analogue for a potential mineral product of subsurface CO2 storage for greenhouse gas reduction. Marine and Petroleum Geology, Vol. 23, Issue. 1, p. 61.

Tenthorey, Eric and Cox, Stephen F. 2006. Cohesive strengthening of fault zones during the interseismic period: An experimental study. Journal of Geophysical Research: Solid Earth, Vol. 111, Issue. B9,

Jin, G. Torres-Verdín, C. Radaelli, F. and Rossi, E. 2007. Experimental Validation of Pore-Level Calculations of Static and Dynamic Petrophysical Properties of Clastic Rocks.

Giger, Silvio B. Tenthorey, Eric Cox, Stephen F. and Fitz Gerald, John D. 2007. Permeability evolution in quartz fault gouges under hydrothermal conditions. Journal of Geophysical Research: Solid Earth, Vol. 112, Issue. B7,

Assouline, S. and Or, D. 2008. Air entry–based characteristic length for estimation of permeability of variably compacted earth materials. Water Resources Research, Vol. 44, Issue. 11,

Baraka-Lokmane, S. Main, I. G. Ngwenya, B. T. Elphick, S. C. Jones, C. and Hamilton, S. A. 2009. Correlation Between Microstructure and Flow Behavior in Porous Sandstones. Petroleum Science and Technology, Vol. 27, Issue. 5, p. 511.

Download full list

Article contents

Analysis of permeability controls: a new approach

Abstract

Access options

References

This article has been cited by the following publications. This list is generated based on data provided by Crossref.

Article contents

Analysis of permeability controls: a new approach

Abstract

Access options

References

Save article to Kindle

Save article to Dropbox

Save article to Google Drive

Reply to: Submit a response

Your details

You have entered the maximum number of contributors

Conflicting interests