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Wave Velocities in Sediments

Published online by Cambridge University Press:  28 February 2011

Dominique Marion ,
Amos Nur  and
Hezhu Yin
Dominique Marion
Affiliation:
Elf Aquitane, Pau, France
Amos Nur
Affiliation:
Rockphysics Laboratory, Department of Geophysics, Stanford University
Hezhu Yin
Affiliation:
Rockphysics Laboratory, Department of Geophysics, Stanford University
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Abstract

Systematic relations between porosity and compressional velocity Vp in the three component (sand, grains, clay and brine) systems (1) porous sandstone, (2) sands, and (3) suspensions, were obtained using experimental data and models. In Cemented Shaley Sandstones Vp was found to correlate linearly with porosity and clay content. The velocities in clean sandstones are about 7% higher than those predicted by the linear fit, indicating that a small amount of clay significantly reduces the elastic moduli of sandstones.

For uncemented shaley sand, a model for the dependence of sonic velocity and porosity on clay content and compaction was developed for sand with clay dispersed in the pore space and for shale with suspened sand grains. The model closely mimics the experimentally observed minimum for porosity and the peak in velocity versus clay content. The results explain much of the scatter in velocity data in-situ. Velocity in suspensions at ϕ = 39% of grains in brine is close to values predicted by the Reuss (Isostress) average. Velocity dispersion, as suggested by Biot (1956 a,b) is calculated and observed in coarser sediments such as sand, whereas velocities in the finer clay and silt follow Biot's low frequency value.

In total, our results provide the complete dependence of velocity on porosity in brine saturated sediment with clays, ranging from pure quartz to pure clay and water. Our results also highlight the crucial role of the critical porosity ϕ at about 39%, and the transition from cemented to uncemented sands.

Type
Research Article
Information
MRS Online Proceedings Library (OPL) , Volume 195: Symposium S – Physical Phenomena in Granular Materials , 1990 , 459
Copyright
Copyright © Materials Research Society 1990

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References

REFERENCES

1. Akal, T., 1972, The relationship between the physical properties of underwater sediments that affect bottom reflection: Marine Geology, 13, 251266.Google Scholar
2. Berryman, J.G., 1980, Confirmation of Biot's theory: Appl. Phys. Lett., 37, 382384.Google Scholar
3. Biot, M.A., 1956, Theory of propagation of elastic waves in a fluid saturated porous solid, 1. Low-frequency range; J. Acoust. Soc. Am., 28, 168178.Google Scholar
4. Biot, M.A., 1956, Theory of propagation of elastic waves in a fluid saturated porous solid, 2. Higher frequency range: J. Acoust. Soc. Am., 28, 179191.Google Scholar
5. Birch, F., 1960, The velocity of compressional waves in rock to 10 kilobars, 1:J. Geophys. Res., 65, 10831102.Google Scholar
6. Clarke, R.H., 1979, Reservoir properties of conglomerates and conglomeratic sandstones: AAPG Bull., 63, 799803.Google Scholar
7. Furnas, C.C., 1928, The relation between specific volume, voids, and size composition in systems of broken solids of mixed sizes: U.S. Bur. Mines, Rept. Investigations, 2894, 110.Google Scholar
8. Gassman, F., 1951, Elastic waves through a packing of spheres: Geophysics, 16, 673685.Google Scholar
9. Hamilton, E.L., 1956, Low sound velocities in high porosity sediments: J. Acoust. Soc. Am., 28, 1619.Google Scholar
10. Hamilton, E.L., 1978, Sound velocity-density relations insea-floor sediments and rocks: J. Acoust. Soc. Am., 63, 366377.Google Scholar
11. Han, D., Nur, A., and Morgan, D., 1986, Effect of porosity and clay content on wave velocity in sandstones: Geophysics, 51, 20932107.Google Scholar
12. Marion, D., 1990, Acoustical, Mechanical and Transport Properties of Sediments and Granular Materials, Ph.D. Thesis, Stanford Univ.Google Scholar
13. McGeary, R.K., 1961, Mechanical packing of spherical particles: J. Am. Ceram. Soc., 44, 513522.Google Scholar
14. Nafe, J.E., Drake, C.L., 1957, Variation with depth in shallow and deep water marine sediments of porosity, density and the velocities of compressional and shear waves: Geophys., 22, 523552.Google Scholar
15. Raymer, D.S., Hunt, E.R., and Gardner, J.S., 1980, An improved sonic transit time-to-porosity transform: Presented at the Soc. Prof. Well Log Anal. 21st Ann. Mtg., paper P. 16. Reuss, A., 1929, Berechnung der fliessgrense von mischkristallen auf grund der plastizitatsbedingung fur einkristalle: Zeitschrift fur Angewandte Mathematik and Mechanik, 9, 49-58.Google Scholar
17. Shumway, G., 1958, Sound velocity versus temperature in water-saturated sediments: Geophys. 23, 494505.Google Scholar
18. Shumway, G., 1960, Sound speed and absorption studies of marine sediments by a resonance method, part II: Geophys., 25, 659682.Google Scholar
19. Smith, D.T., 1974, Acoustic and mechanical loading of marine sediments, Physics of Sound in Marine Sediments, edited by Hampton, L.D., Plenum, New York.Google Scholar
20. Voigt, W., 1928, Lehrbuch der Kristallphysik, Teubner, Leipzig. Macmillan, New York.Google Scholar
21. Westman, A.E.R., and Hugill, H.R., 1930, The packing of particles: J. Am. Ceram. Soc., 13, 767779.Google Scholar
22. Wood, A.B., 1941, A Textbook of sound. Macmillan, New York.Google Scholar
23. Yin, H., Han, D.H., and Nur, A., 1988, Study of velocity and compaction on sand-clay mixtures, Stanford Rock and Borehole Project, Vol. 33.Google Scholar