Clay Mineral Cements in Sandstones

Clay minerals are one of the most important groups of minerals that destroy permeability in sandstones. However, they also react with drilling and completion fluids and induce fines migration during hydrocarbon production. They are a very complex family of minerals that are routinely intergrown with each other, contain a wide range of solid solutions and form by a variety of processes under a wide range temperatures and rock and fluid compositions.

In this volume, clay minerals in sandstones are reviewed in terms of their mineralogy and general occurrence, their stable and radiogenic isotope geochemistry, XRD quantification, their effects on the petrophysical properties of sandstones and their relationships to sequence stratigraphy and palaeoclimate. The controls on various clay minerals are addressed and a variety of geochemical issues, including the importance of mass flux, links to carbonate mineral diagenesis and linked clay mineral diagenesis in interbedded mudstone-sandstone are explored. A number of case studies are included for kaolin, illite and chlorite cements, and the occurrence of smectite in sandstone is reviewed. Experimental rate data for clay cements in sandstones are reviewed and there are two model-based case studies that address the rates of growth of kaolinite and illite.

The readership of this volume will include sedimentologists and petrographers who deal with the occurrence, spatial and temporal distribution patterns and importance of clay mineral cements in sandstones, geochemists involved in unraveling the factors that control clay mineral cement formation in sandstones and petroleum geoscientists involved in predicting clay mineral distribution in sandstones. The book will also be of interest to geologists involved in palaeoclimate studies basin analysis.

• Latest geochemical data on clays in sandstones

• Provides important information for geologists involved in basin analysis, sandstone petrology and petroleum geology

If you are a member of the International Association of Sedimentologists (IAS), for purchasing details, please see: http://www.iasnet.org/publications/details.asp?code=SP34

Auteur

Richard Worden is the editor of Clay Mineral Cements in Sandstones, published by Wiley. Sadoon Morad is the editor of Clay Mineral Cements in Sandstones, published by Wiley.

Contenu
Review papers.

1. Clay minerals in sandstones: controls on formation,
   distribution and evolution: R. H. Worden and S. Morad.

2. Predictive diagenetic clay-mineral distribution in
   siliciclastic rocks within a sequence stratigraphic framework: J.M.
   Ketzer, S. Morad and A. Amorosi.

3. Oxygen and hydrogen isotope composition of diagenetic clay
   minerals in sandstones: a review of the data and controls: S.
   Morad, R. H. Worden and J.M. Ketzer.

4. Palaeoclimate controls on spectral gamma-ray radiation from
   sandstones: A. Ruffell, R.H. Worden and R. Evans.

5. Smectite in sandstones: a review of the controls on
   occurrence and behaviour during diagenesis: J. M. McKinley, R. H.
   Worden and A. H. Ruffell.

6. Patterns of clay mineral diagenesis in interbedded mudrocks
   and sandstones: an example from the Palaeocene of the North Sea:
   H.F. Shaw and D.M. Conybeare, D.M.

7. Cross-formational flux of aluminium and potassium in Gulf
   Coast (USA) sediments:M. Wilkinson, R.S. Haszeldine and K.L.
   Milliken.

8. Silicate-carbonate reactions in sedimentary systems: fluid
   composition control and potential for generation of overpressure:
   I. Hutcheon and S. Desrocher.

9. Experimental studies of clay mineral occurrence: D. A. C.
   Manning.

10. Effect of clay content upon some physical properties of
    sandstone reservoirs: Paul F. Worthington.

11. Quantitative analysis of clay and other minerals in
    sandstones by X-ray powder diffraction (XRPD): S. Hillier.

12. A review of radiometric dating techniques for clay mineral
    cements in sandstones: P. J. Hamilton.

Chlorite case study.

13. Chlorite authigenesis and porosity preservation in the Upper
    Cretaceous marine sandstones of the Santos Basin, offshore eastern
    Brazil: S. M. C. Anjos, L. F. De Ros and C. M. A. Silva.

Kaolinite case studies.

14. Origin and diagenetic evolution of kaolin in reservoir
    sandstones and associated shales of the Jurassic and Cretaceous,
    Salam Field, Western Desert (Egypt): R. Marfil, A. Delgado, C.
    Rossi, A. La Iglesia and K. Ramseyer.

15. Microscale distribution of kaolinite in Breathitt Formation
    sandstones (middle Pennsylvanian): implications for mass balance:
    K. L. Milliken.

16. The role of the Cimmerian unconformity (Early Cretaceous) in
    the kaolinitization and related reservoir-quality evolution in
    Triassic sandstones of the Snorre Field, North Sea: J.M. Ketzer, S.
    Morad, J.P. Nystuen and L.F. De Ros.

17. The formation and stability of kaolinite in Brent sandstone
    reservoirs: a modelling approach: É. Brosse, T. Margueron, C.
    Cassou, B. Sanjuan, A. Canham, J.-P. Girard, J.-C. Lacharpagne and
    F. Sommer.

Illite case studies.

18. Illite fluorescence microscopy: a new technique in the study
    of illite in the Merrimelia Formation, Cooper Basin, Australia: N.
    M. Lemon and C. J. Cubitt.

19. Geochemical modelling of diagenetic illite and quartz cement
    formation in Brent sandstone reservoirs: example of the Hild Field,
    Norwegian North Sea: B. Sanjuan, J.-P. Girard, S. Lanini, A.
    Bourguignon and E. Brosse.

20. The effect of oil emplacement on diagenetic clay mineralogy:
    the Upper Jurassic Magnus Sandstone Member, North Sea: R.H. Worden
    and S.A. Barclay.

Glauconite case study.

21. Application of glauconite morphology in geosteering and for
    on-site reservoir quality assessment in very fine-grained
    sandstones: Carnarvon Basin, Australia: J.P.Schulz-Rojahn, D.A.
    Seeburger and G.J. Beacher.

Index