1887
  1. Home
  2. A-Z Publications
  3. Geophysical Prospecting
  4. Volume 64, Issue 4
  5. Article
Volume 64 Number 4
  • E-ISSN: 1365-2478

Abstract

ABSTRACT

Development of rock physical properties in well‐sorted and poorly‐sorted unconsolidated mono‐quartz sands and sand–clay mixtures as a function of effective stress in both dry and brine‐saturated conditions is assessed in this study. The tested samples were prepared with full control on their mineralogy, grain size, grain shape, sorting, and fabric. The experiments were performed in a high‐stress uniaxial oedometer up to a maximum of 30 MPa vertical effective stress. Sand–clay samples were a mixture of sand grains and clay particles (kaolinite or smectite) in different proportions. The maximum clay volume fraction used in the experiments was at most 30%. The initial bulk density of the tested sand‐dominated samples was adjusted to be close to the maximum index density expected for natural sediments (sand–clay mixtures) during deposition.

In pure sand samples, finer grained sand show higher initial porosity than relatively coarser grained sands. Moreover, sand–clay mixtures have lower initial porosity than pure sands. Porosity decreases as a function of increasing clay content. The poorly‐sorted sand samples are less compaction prone than the well‐sorted sand samples. Among well‐sorted sand samples, coarser grained sands are more compressible than finer grained sands. At a given effective stress level, sand–clay mixtures are more compaction prone compared with their sand component alone. Pure sands and clay‐poor sand–clay mixtures (either sand–kaolinite or sand–smectite) show almost the same degree of compaction when tested in both dry and brine‐saturated conditions. In contrast, clay‐rich sand–kaolinite and sand–smectite mixtures (clay volume >20%) are significantly more compact in brine‐saturated condition. The V values of brine‐saturated sand–kaolinite mixtures shows a positive correlation with the kaolinite content, whereas V starts to decrease substantially when the volume fraction of smectite exceeds 10% of the whole sand–smectite samples.

Saturated bulk moduli estimated by Gassmann's fluid substitution agree with measurements for brine‐saturated clay‐poor sand samples. However, the model does not yield proper predictions for sand–clay samples containing 20% clay volume and above, particularly when the clay is mainly smectite. The acoustic and physical properties derived from experimental compaction of pure sands and sand–clay mixtures show a good agreement with rock properties derived from well logs of mechanically compacted pure sands and shaly sands in progressively subsided basins such as Viking Graben in the North Sea. Thus, the outcome of this study can provide reliable constraints for rock physical properties of sands and shaly sands within the mechanical compaction domain and contribute to improved basin modelling and identification of hydrocarbon presence, overconsolidation, and/or undercompaction.

© 2016 European Association of Geoscientists & Engineers © 2016 European Association of Geoscientists & Engineers
Loading

Article metrics loading...

/content/journals/10.1111/1365-2478.12399
2016-06-13
2024-04-26

  • From This Site

    /content/journals/10.1111/1365-2478.12399
    dcterms_title,dcterms_subject,pub_keyword
    -contentType:Journal -contentType:Contributor -contentType:Concept -contentType:Institution
    10
    5
Loading full text...

Full text loading...

References

  1. AdamL., BatzleM. and BrevikI.2006. Gassmann's fluid substitution and shear modulus variability in carbonates at laboratory seismic and ultrasonic frequencies. Geophysics71(6), F173–F183.
     [Google Scholar]
  2. AndersenC.F. and JohansenT.A.2010. Test of rock physics models for prediction of seismic velocities in shallow unconsolidated sands: a well log data case. Geophysical Prospecting58, 1083–1098.
     [Google Scholar]
  3. ASTM
    ASTM2015a. Standard Test Methods for Minimum Index Density and Unit Weight of Soils and Calculation of Relative Density. American Society for Testing and Materials.
     [Google Scholar]
  4. ASTM
    ASTM2015b. Standard Test Methods for Maximum Index Density and Unit Weight of Soils Using a Vibratory Table. American Society for Testing and Materials.
     [Google Scholar]
  5. BachrachR. and AvsethP.2008. Rock physics modeling of unconsolidated sands: Accounting for nonuniform contacts and heterogeneous stress fields in the effective media approximation with applications to hydrocarbon exploration. Geophysics73(6), E197–E209.
     [Google Scholar]
  6. BachrachR., DvorkinJ. and NurA.M.2000. Seismic velocities and Poisson's ratio of shallow unconsolidated sands. Geophysics65, 559–564.
     [Google Scholar]
  7. BatzleM. and WangZ.1992. Seismic properties of pore fluids. Geophysics57, 1396–1408.
     [Google Scholar]
  8. BerrymanJ.G.1999. Origin of Gassmann's equations. Geophysics64, 1627–1629.
     [Google Scholar]
  9. BiotM.A.1956. Theory of propagation of elastic waves in a fluid saturated porous solid, I. Low‐frequency range, II. Higher frequency range. The Journal of the Acoustical Society of America28, 168–191.
     [Google Scholar]
  10. BirchF.1960. The velocity of compressional waves in rocks to 10 kilobars: Part 1. Journal of Geophysical Research65, 1083–1102.
     [Google Scholar]
  11. BjørlykkeK. and JahrenJ.2010. Sandstones and sandstone reservoirs. In: Petroleum Geoscience: From Sedimentary Environments to Rock Physics (ed K.Bjørlykke ), pp. 113–141. Springer.
     [Google Scholar]
  12. BjørlykkeK., RammM. and SaigalG.1989. Sandstone diagenesis and porosity modification during basin evolution. Geologische Rundschau78, 243–268.
     [Google Scholar]
  13. BrevikI.1996. Inversion and analysis of Gassmann skeleton properties of shaly sandstones using wireline log data from the Norwegian North Sea. 66th SEG meeting, Denver, USA, Expanded Abstracts, P130.
  14. CarmichaelR.S.1989. Practical Handbook of Physical Properties of Rocks and Minerals. CRC Press, London.
     [Google Scholar]
  15. CastagnaJ.P., BatzleM.L. and EastwoodR.L.1985. Relationships between compressional‐wave and shear‐wave velocities in clastic silicate rocks. Geophysics50, 571–581.
     [Google Scholar]
  16. ChuhanF.A., KjeldstadA., BjørlykkeK. and HøegK.2003. Experimental compression of loose sands: relevance to porosity reduction during burial in sedimentary basins. Canadian Geotechnical Journal40, 995–1011.
     [Google Scholar]
  17. DuttaT., MavkoG. and MukerjiT.2010. Improved granular medium model for unconsolidated sands using coordination number, porosity, and pressure relations. Geophysics75(2), E91–E99.
     [Google Scholar]
  18. DvorkinJ. and NurA.1993. Dynamic poroelasticity: A unified model with the squirt and the Biot mechanisms. Geophysics58, 524–533.
     [Google Scholar]
  19. DvorkinJ. and NurA.1996. Elasticity of high‐porosity sandstones: Theory for two North Sea data sets. Geophysics61, 1363–1370.
     [Google Scholar]
  20. Eberhart‐PhillipsD., HanD.H. and ZobackM.D.1989. Empirical relationships among seismic velocity, effective pressure, porosity, and clay content in sandstone. Geophysics54, 82–89.
     [Google Scholar]
  21. FaleideJ.I., KyrkjebøR., KjennerudT., GabrielsenR.H., JordtH., FanavollS.et al. 2002. Tectonic impact on sedimentary processes during Cenozoic evolution of the northern North Sea and surrounding areas. Special Publication‐Geological Society of London196, 235–269.
     [Google Scholar]
  22. FawadM., MondolN.H., JahrenJ. and BjørlykkeK.2011. Mechanical compaction and ultrasonic velocity of sands with different texture and mineralogical composition. Geophysical Prospecting59, 697–720.
     [Google Scholar]
  23. GassmannF.1951. Elastic waves through a packing of spheres. Geophysics16, 673–685.
     [Google Scholar]
  24. HanD.H. and BatzleM.L.2004. Gassmann's equation and fluid‐saturation effects on seismic velocities. Geophysics69, 398–405.
     [Google Scholar]
  25. HanD.H., NurA. and MorganD.1986. Effects of porosity and clay content on wave velocities in sandstones. Geophysics51, 2093–2107.
     [Google Scholar]
  26. HashinZ. and ShtrikmanS.1963. A variational approach to the theory of the elastic behaviour of multiphase materials. Journal of the Mechanics and Physics of Solids11, 127–140.
     [Google Scholar]
  27. KataharaK.W.1996. Clay mineral elastic properties. 66th SEG meeting, Denver, USA, Expanded Abstracts, P1691.
  28. KlimentosT.1991. The effects of porosity‐permeability‐clay content on the velocity of compressional waves. Geophysics56, 1930–1939.
     [Google Scholar]
  29. KumarD., HampsonD.P., RussellB.H., BankheadB., BlandS., GriffithsP.et al. 2006. A tutorial on Gassmann fluid substitution: formulation, algorithm and Matlab code. Geohorizons2, 4–12.
     [Google Scholar]
  30. LaddR.S.1978. Preparing test specimens using undercompaction. Geotechnical Testing Journal1, 16–23.
     [Google Scholar]
  31. MarionD., NurA., YinH. and HanD.1992. Compressional velocity and porosity in sand–clay mixtures. Geophysics57, 554–563.
     [Google Scholar]
  32. MavkoG., MukerjiT. and DvorkinJ.2009. The Rock Physics Handbook: Tools for Seismic Analysis in Porous Media. Cambridge University Press.
     [Google Scholar]
  33. MindlinR.D.1949. Compliance of elastic bodies in contact. Journal of Applied Mechanics16, 259–268.
     [Google Scholar]
  34. MondolN.H.2009. Porosity and permeability development in mechanically compacted silt‐kaolinite mixtures. 79th SEG meeting, Houston, USA, Expanded Abstracts, P 2139.
  35. MondolN.H.2015. Experimental compaction of dry smectite‐silt mixtures. 3rd International Workshop on Rock Physics, Perth, Australia, Expanded Abstracts.
  36. MondolN.H., BjørlykkeK. and JahrenJ.2008a. Experimental compaction of clays: relationship between permeability and petrophysical properties in mudstones. Petroleum Geoscience14, 319–337.
     [Google Scholar]
  37. MondolN.H., BjørlykkeK., JahrenJ. and HøegK.2007. Experimental mechanical compaction of clay mineral aggregates‐Changes in physical properties of mudstones during burial. Marine and Petroleum Geology24, 289–311.
     [Google Scholar]
  38. MondolN.H., JahrenJ., BjørlykkeK. and BrevikI.2008b. Elastic properties of clay minerals. The Leading Edge27, 758–770.
     [Google Scholar]
  39. MurphyW.1982. Effects of microstructure and pore fluids on the acoustic properties of granular sedimentary materials. Ph.D. dissertation, Stanford University.
     [Google Scholar]
  40. NarongsirikulS., MondolN.H. and JahrenJ.2013. Density/porosity versus velocity of overconsolidated sands derived from experimental compaction. 75th EAGE Conference and Exhibition incorporating SPE EUROPEC, London, U.K., Expanded Abstracts.
  41. NPD
    NPD2015. Norwegian Petroleum Directorate Fact Pages.
     [Google Scholar]
  42. PrasadM. and MeissnerR.1992. Attenuation mechanisms in sands: Laboratory versus theoretical (Biot) data. Geophysics57, 710–719.
     [Google Scholar]
  43. RaymerL., HuntE. and GardnerJ.S.1980. An improved sonic transit time‐to‐porosity transform. In: SPWLA 21st Annual Logging Symposium. Society of Petrophysicists and Well‐Log Analysts.
     [Google Scholar]
  44. RevilA., GraulsD. and BrévartO.2002. Mechanical compaction of sand/clay mixtures. Journal of Geophysical Research107(B11), ECV 11‐1–ECV 11‐15.
     [Google Scholar]
  45. SmithT.M., SondergeldC.H. and RaiC.S.2003. Gassmann fluid substitutions: a tutorial. Geophysics68, 430–440.
     [Google Scholar]
  46. SwarbrickR.E. and OsborneM.J.1998. Mechanisms that generate abnormal pressures: An overview. In: AAPG Memoir Vol. 70: Abnormal Pressures in Hydrocarbon Environments (eds B.E.Law , G.F.Ulmishek and U.I.Slavin ), pp. 13–34.
     [Google Scholar]
  47. ThybergB., JordtH., BjorlykkeK. and FaleideJ.2000. Relationships between sequence stratigraphy, mineralogy and geochemistry in Cenozoic sediments of the northern North Sea. Special Publication‐Geological Society of London167, 245–272.
     [Google Scholar]
  48. Van OlphenH. and FripiatJ.J.1979. Data Handbook for Clay Materials and Other Nonmetallic Minerals. Pergamon Press, University of Michigan.
     [Google Scholar]
  49. VanorioT., PrasadM. and NurA.2003. Elastic properties of dry clay mineral aggregates, suspensions and sandstones. Geophysical Journal International155, 319–326.
     [Google Scholar]
  50. WalderhaugO.2000. Modeling quartz cementation and porosity in Middle Jurassic Brent Group sandstones of the Kvitebjørn field, northern North Sea. AAPG bulletin84, 1325–1339.
     [Google Scholar]
  51. WaltonK.1987. The effective elastic moduli of a random packing of spheres. Journal of the Mechanics and Physics of Solids35, 213–226.
     [Google Scholar]
  52. WinklerK.W.1985. Dispersion analysis of velocity and attenuation in Berea sandstone. Journal of Geophysical Research90, 6793–6800.
     [Google Scholar]
  53. WyllieM.R.J., GregoryA.R. and GardnerL.W.1956. Elastic wave velocities in heterogeneous and porous media. Geophysics21, 41–70.
     [Google Scholar]
  54. YinH.1992. Acoustic velocity and attenuation of rocks: isotropy, intrinsic anisotropy, and stress induced anisotropy. Ph.D. dissertation, Stanford University.
     [Google Scholar]
  55. ZimmerM.A., PrasadM., MavkoG. and NurA.2007. Seismic velocities of unconsolidated sands: Part 1 ‐ Pressure trends from 0.1 to 20 MPa. Geophysics72(1), E1–E13.
     [Google Scholar]
http://instance.metastore.ingenta.com/content/journals/10.1111/1365-2478.12399
Loading
Experimental mechanical compaction of sands and sand–clay mixtures: a study to investigate evolution of rock properties with full control on mineralogy and rock texture
Geophysical Prospecting 64, 915 (2016); https://doi.org/10.1111/1365-2478.12399
/content/journals/10.1111/1365-2478.12399
/content/journals/10.1111/1365-2478.12399
Loading

Data & Media loading...

  • Article Type: Research Article
Keyword(s): Reservoir geophysics; Rock physics; Velocity

Most Cited This Month Most Cited RSS feed

This is a required field
Please enter a valid email address
Approval was a Success
Invalid data
An Error Occurred
Approval was partially successful, following selected items could not be processed due to error