Acoustic wave velocity modelling in sedimentary sequences

Michael Wiltshire; Leslle Huggard

doi:10.1071/EG00401

ISSN: 0812-3985
E-ISSN: 1834-7533

Acoustic wave velocity modelling in sedimentary sequences
Authors Michael Wiltshire^a and Leslle Huggard^b
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^a 13 St. Andrews Avenue, Mount Osmond, South Australia, 5064, Phone: (08) 8379 3246, Facsimile: (08) 8379 7732, E-mail: [email protected] ^b 10 Barker Road, Mount Barker, South Australia, 5251, Phone: (08) 8398 3256, Facsimile: (08) 8379 7732, E-mail: [email protected]
Publisher: Australian Society of Exploration Geophysicists
Source: Exploration Geophysics, Volume 31, Issue 1-2, Mar 2000, p. 401 - 408
DOI: https://doi.org/10.1071/EG00401
- Published online: 01 Mar 2000

Abstract

Layered-clay shale density increases systematically with increasing depth of burial by progressive expulsion of pore water: $ρ(z)= ρ0+ (ρ∞ − ρ0)(1 − e−kz)$

Using elastic wave propagation theory, this shale density function can be transformed into a shale velocity prediction. Providing shale and water chemistry remain relatively stable, the progressive reduction in shale porosity and contained water also results in systematic changes to shale resistivity.

More general formation (mixed lithology) sonic slowness can be modelled using established log interpretation transforms (the Archie porosity - resistivity and Raymer-Hunt-Gardner porosity - slowness relationships). The difference between measured formation resistivity and predicted shale resistivity is then interpreted in terms of departure of the expected slowness from that of pure shale. When added to the expected shale slowness, the combined slowness shows good agreement with observed sonic log data.

This provides a new technique for prediction of formation velocities. The technique can be used to improve the quality of sonic log data, and can be applied where no sonic data were acquired. Numerous technical and commercial applications result.

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References

Alberty, M., 1996. The influence of the borehole environment upon compressional sonic logs: The Log Analyst, v. 37, No. 4, p. 30 - 44.
Al-Chalabi, M., 1997. Parameter nonuniqueness in velocity versus depth functions: Geophysics, v. 62, No. 3, p. 970 - 979.
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Gassman, F., 1951. Elastic waves through a packing of spheres: Geophysics, v. 50, p 673 - 685.
Gearhart Formation Evaluation Data Handbook, 1982: Gearhart Industries, Fort Worth, Texas.
Goetz, J.R., Dupal, L. and Bowler, J., 1979. An investigation into discrepancies between sonic log and seismic checkshot velocities: APEA Journal, v. 19, Part 2, p. 131 - 141.
Gorbachev, Y. L., 1995. Well logging: Fundamentals of methods: John Wiley and Sons, 324 p.
Khaksar, A., Griffiths, C.M. and McCann, C., 1999 (a). Compressional- and shear-wave velocities as a function of confining stress in dry sandstones: Geophysical Prospecting, v. 47, p. 487 - 508.
Korvin, G., 1984. Shale compaction and statistical physics: Geophysical Journal of the Royal Astronomical Society, v. 78, p. 35 - 50.
Lander, R.H. and Walderhaugh, O., 1999. Predicting porosity through simulating sandstone compaction and quartz cementation: AAPG Bulletin, v. 83, No. 3, p. 433 - 449.

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Article Type: Research Article

Keyword(s): acoustic log; acoustic modelling; compressional wave propagation; elastic wave theory; Exponential shale compaction; resistivity log

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Acoustic wave velocity modelling in sedimentary sequences

Abstract

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