Changes in P-wave velocity with different full waveform sonic transmitter centre frequency

Majed Almalki; Brett Harris; J. Christian Dupuis

doi:10.1071/EG13037

RESEARCH ARTICLE

Previous Next Contents Vol 46(2)

Changes in P-wave velocity with different full waveform sonic transmitter centre frequency

Majed Almalki ¹ ² ⁴ Brett Harris ¹ J. Christian Dupuis ¹ ³

+ Author Affiliations

- Author Affiliations

¹ Department of Exploration Geophysics, Curtin University, Perth, WA 6845, Australia.

² King Abdulaziz City for Science and Technology, Oil and Gas Research Institute, PO Box 6086, Riyadh 11442, Saudi Arabia.

³ Université Laval, Department of Geology and Geological Engineering, Québec G1V 0A6, Canada.

⁴ Corresponding author. Email: malmalki@kacst.edu.sa

Exploration Geophysics 46(2) 192-205 https://doi.org/10.1071/EG13037
Submitted: 24 April 2013 Accepted: 26 March 2014 Published: 13 May 2014

Abstract

Full waveform sonic logging, with the transmitter set at different centre frequencies, often provides different compressional wave velocities over the same interval. There may be several reasons why these velocity differences are recovered where the source has different frequency content. Examples include: intrinsic dispersion, scattering dispersion, geometric dispersion, processing artefacts and acquisition artefacts. We acquired and analysed multifrequency monopole full waveform sonic logging data from the cored drill hole intersecting a high-permeability sandy aquifer in the Northern Gnangara Mound, Perth Basin, Western Australia. A key interval of the shallow, sand-dominated Yarragadee Formation was selected and logged four times with transmitter centre frequencies set to 1, 3, 5 and 15 kHz. We compute apparent velocity dispersion as the percentage velocity differences in the P-wave velocity recovered from full waveform sonic logs completed at different dominant transmitter centre frequencies. We find that high-permeability sediments could be placed into broad groups: cross-bedded and non-cross-bedded sandstones.

We find a distinctly different relationship between apparent P-wave velocity dispersion and permeability for cross-bedded and non-cross-bedded sandstones. Cross plots for the two sediment types show a general trend of increasing apparent dispersion with increasing permeability. Grouping the sandstone layers based on sediment type, as observed from core samples, illustrates different but positive correlation between the apparent P-wave velocity dispersion and permeability in these shallow, weakly-consolidated sandstones. The cross-bedded sandstone, for its part, has a wider range of permeability than the non-cross-bedded sandstone but a smaller range of apparent P-wave velocity dispersion. Given these results, our hypothesis is that while permeability plays a role, other factors such as geometric dispersion or scattering dispersion likely contribute the net value of P-wave dispersion recovered between any two receivers. Finally the results from these experiments have shown that there exists at least a weak empirical relationship between P-wave velocity dispersion and hydraulic permeability at the field site.

Key words: FWS logging, high permeability, multifrequency, soft sediments, velocity dispersion.

References

Almalki, M., Harris, B., and Dupuis, J. C., 2012, Stoneley wave dispersion in high permeability sandstone: Perth Basin, Western Australia: ASEG Extended Abstracts, 1–4.

Almalki, M., Harris, B., and Dupuis, C. J., 2013, Multifrequency full-waveform sonic logging in the screened interval of a large-diameter production well: Geophysics, 78, B243–B257
| Multifrequency full-waveform sonic logging in the screened interval of a large-diameter production well:Crossref | GoogleScholarGoogle Scholar |

Ba, J., Nie, J. X., Cao, H., and Yang, H. Z., 2008a, Mesoscopic fluid flow simulation in double-porosity rocks: Geophysical Research Letters, 35, L04303
| Mesoscopic fluid flow simulation in double-porosity rocks:Crossref | GoogleScholarGoogle Scholar |

Ba, J., Cao, H., Yao, F. C., Nie, J. X., and Yang, H. Z., 2008b, Double-porosity rock model and squirt flow in laboratory frequency band: Applied Geophysics, 5, 261–276
| Double-porosity rock model and squirt flow in laboratory frequency band:Crossref | GoogleScholarGoogle Scholar |

Batzle, M., Han, D., and Hofmann, R., 2006, Fluid mobility and frequency-dependent seismic velocity –direct measurements: Geophysics, 71, N1–N9

Best, A. I., and Sams, M. S., 1997, Compressional wave velocity and attenuation at ultrasonic and sonic frequencies in near‐surface sedimentary rocks: Geophysical Prospecting, 45, 327–344
| Compressional wave velocity and attenuation at ultrasonic and sonic frequencies in near‐surface sedimentary rocks:Crossref | GoogleScholarGoogle Scholar |

Biot, M. A., 1956a, Theory of propagation of elastic waves in fluid-saturated porous solid. I. Low-frequency range: The Journal of the Acoustical Society of America, 28, 168–178
| Theory of propagation of elastic waves in fluid-saturated porous solid. I. Low-frequency range:Crossref | GoogleScholarGoogle Scholar |

Biot, M. A., 1956b, Theory of propagation of elastic waves in a fluid-saturated porous solid. II. Higher frequency range: The Journal of the Acoustical Society of America, 28, 179–191
| Theory of propagation of elastic waves in a fluid-saturated porous solid. II. Higher frequency range:Crossref | GoogleScholarGoogle Scholar |

Biot, M. A., 1962, Mechanics of deformation and acoustic propagation in porous media: Journal of Applied Physics, 33, 1482–1498
| Mechanics of deformation and acoustic propagation in porous media:Crossref | GoogleScholarGoogle Scholar |

Bourbie, T., Coussy, O., and Zinszner, B., 1987, Acoustics of porous media: Gulf Publishing Company, Paris.

Caspari, E., Gurevich, B., and Müller, T. M., 2013, Frequency-dependent effective hydraulic conductivity of strongly heterogeneous media: Physical Review E: Statistical, Nonlinear, and Soft Matter Physics, 88, 042119
| Frequency-dependent effective hydraulic conductivity of strongly heterogeneous media:Crossref | GoogleScholarGoogle Scholar | 1:STN:280:DC%2BC2c7mslCiuw%3D%3D&md5=ab5e0d8a614f6e0df9269c2091026893CAS |

David, E., and Zimmerman, R., 2013, Model for frequency-dependence of elastic wave velocities in porous rocks, in C. Hellmich, B. Pichler, and D. Adam, eds., Poromechanics V: Proceedings of the Fifth Biot Conference on Poromechanics: American Society of Civil Engineers, 2431–2440.

Dutta, N., and Odé, H., 1979, Attenuation and dispersion of compressional waves in fluid-filled porous rocks with partial gas saturation (White model) – Part I: Biot theory: Geophysics, 44, 1777–1788
| Attenuation and dispersion of compressional waves in fluid-filled porous rocks with partial gas saturation (White model) – Part I: Biot theory:Crossref | GoogleScholarGoogle Scholar |

Gelinsky, S., and Shapiro, S. A., 1997, Dynamic-equivalent medium approach for thinly layered saturated sediments: Geophysical Journal International, 128, F1–F4
| Dynamic-equivalent medium approach for thinly layered saturated sediments:Crossref | GoogleScholarGoogle Scholar |

Gurevich, B., and Lopatnikov, S. L., 1995, Velocity and attenuation of elastic waves in finely layered porous rocks: Geophysical Journal International, 121, 933–947
| Velocity and attenuation of elastic waves in finely layered porous rocks:Crossref | GoogleScholarGoogle Scholar |

Gurevich, B., Zyrianov, V. B., and Lopatnikov, S. L., 1997, Seismic attenuation in finely layered porous rocks: effects of fluid flow and scattering: Geophysics, 62, 319–324
| Seismic attenuation in finely layered porous rocks: effects of fluid flow and scattering:Crossref | GoogleScholarGoogle Scholar |

Han, D. H., and Nur, A., 1987, Velocity dispersions in sandstones: 57th Annual International Meeting, SEG, Expanded Abstracts, 57, 5–8.

Harris, B., Kepic, A., and Dupuis, J. C., 2010, Acquisition and processing report: seismic reflection and ground penetration radar transects across the northern Gnangara Mound, Perth Basin, Western Australia: Curtin University, Department of Exploration Geophysics.

Johnston, D. H., Toksöz, M., and Timur, A., 1979, Attenuation of seismic waves in dry and saturated rocks: II. Mechanisms: Geophysics, 44, 691–711
| Attenuation of seismic waves in dry and saturated rocks: II. Mechanisms:Crossref | GoogleScholarGoogle Scholar |

Jones, T. D., 1986, Pore fluids and frequency-dependent wave propagation in rock: Geophysics, 51, 1939–1953
| Pore fluids and frequency-dependent wave propagation in rock:Crossref | GoogleScholarGoogle Scholar |

Khan, M. A., and Rees, A. I., 1967, Dispersion of seismic waves, in S. K. Runcorn, ed., International dictionary of geophysics: Pergamon, 2, 804.

Li, M., and Mason, I., 2000, Interactive seismic event recognition and its applications: Exploration Geophysics, 31, 469–472
| Interactive seismic event recognition and its applications:Crossref | GoogleScholarGoogle Scholar |

Markova, I., Ronquillo, G., Markov, M., and Gurevich, B., 2014, Squirt flow influence on sonic log parameters: Geophysical Journal International, 196, 1082–1091
| Squirt flow influence on sonic log parameters:Crossref | GoogleScholarGoogle Scholar |

Mavko, G. M., and Nur, A., 1975, Melt squirt in the asthenosphere: Journal of Geophysical Research, 80, 1444–1448
| Melt squirt in the asthenosphere:Crossref | GoogleScholarGoogle Scholar |

Mavko, G. M., and Nur, A., 1979, Wave attenuation in partially saturated rocks: Geophysics, 44, 161–178
| Wave attenuation in partially saturated rocks:Crossref | GoogleScholarGoogle Scholar |

McCormack, M. D., Zaucha, D. E., and Dushek, D. W., 1993, First-break refraction event picking and seismic data trace editing using neural networks: Geophysics, 58, 67–78
| First-break refraction event picking and seismic data trace editing using neural networks:Crossref | GoogleScholarGoogle Scholar |

Mount Sopris Instruments Inc., 2002, 2SAA-1000/F Sonic Probe: Colorado, USA.

Müller, T. M., and Gurevich, B., 2005, Wave-induced fluid flow in random porous media: attenuation and dispersion of elastic waves: The Journal of the Acoustical Society of America, 117, 2732–2741
| Wave-induced fluid flow in random porous media: attenuation and dispersion of elastic waves:Crossref | GoogleScholarGoogle Scholar | 15957744PubMed |

Müller, T. M., Gurevich, B., and Shapiro, S. A., 2008, Attenuation of seismic waves due to wave-induced flow and scattering in random porous media, in H. Sato, and M. Fehler, eds., Earth heterogeneity and scattering effects on seismic waves: Elsevier, 123–166.

Müller, T. M., Gurevich, B., and Lebedev, M., 2010, Seismic wave attenuation and dispersion resulting from wave-induced flow in porous rocks – a review: Geophysics, 75, 75A147–75A164
| Seismic wave attenuation and dispersion resulting from wave-induced flow in porous rocks – a review:Crossref | GoogleScholarGoogle Scholar |

Murphy, W. M., Winkler, K. W., and Kleinberg, R. L., 1984, Frame modulus reduction in sedimentary rocks: the effect of adsorption on grain contacts: Geophysical Research Letters, 11, 805–808
| Frame modulus reduction in sedimentary rocks: the effect of adsorption on grain contacts:Crossref | GoogleScholarGoogle Scholar |

Norris, A. N., 1993, Low-frequency dispersion and attenuation in partially saturated rocks: The Journal of the Acoustical Society of America, 94, 359–370
| Low-frequency dispersion and attenuation in partially saturated rocks:Crossref | GoogleScholarGoogle Scholar |

O’Connell, R. J., and Budiansky, B., 1977, Viscoelastic properties of fluid-saturated cracked solids: Journal of Geophysical Research, 82, 5719–5735
| Viscoelastic properties of fluid-saturated cracked solids:Crossref | GoogleScholarGoogle Scholar |

Palmer, I. D., and Traviolia, J. L., 1980, Attenuation by squirt flow in under-saturated gas sands: Geophysics, 45, 1780–1792
| Attenuation by squirt flow in under-saturated gas sands:Crossref | GoogleScholarGoogle Scholar |

Prasad, M., 2003, Velocity-permeability relations within hydraulic units: Geophysics, 68, 108–117
| Velocity-permeability relations within hydraulic units:Crossref | GoogleScholarGoogle Scholar |

Pride, S. R., 2005, Relations between seismic and hydrological properties, in Y. Rubin, and S. S. Hubbard, eds., Hydrogephysics: Springer, 253–290.

Pride, S. R., Harris, J. M., Johnson, D. L., Mateeva, A., Nihei, K. T., Nowackack, R. L., Rector, J. W., Spetzler, H., Wu, R., Yamamoto, T., Berryman, J. G., and Fehler, M., 2003, Permeability dependence of seismic amplitudes: The Leading Edge, 22, 518–525
| Permeability dependence of seismic amplitudes:Crossref | GoogleScholarGoogle Scholar |

Pride, S. R., Berryman, J. G., and Harris, J. M., 2004, Seismic attenuation due to wave-induced flow: Journal of Geophysical Research, 109, B01201
| Seismic attenuation due to wave-induced flow:Crossref | GoogleScholarGoogle Scholar |

Pun, W., Milkereit, B., and Harris, B., 2010, Extracting frequency-dependent velocities from full waveform sonic data: SEG Technical Program, Expanded Abstracts, 4024–4028.

Rubino, J., Ravazzoli, C., and Santos, J., 2009, Equivalent viscoelastic solids for heterogeneous fluid-saturated porous rocks: Geophysics, 74, N1–N13

Rubino, J., Velis, D., and Holliger, K., 2012, Permeability effects on the seismic response of gas reservoirs: Geophysical Journal International, 189, 448–468
| Permeability effects on the seismic response of gas reservoirs:Crossref | GoogleScholarGoogle Scholar |

Rubino, J. G., Monachesi, L. B., Müller, T. M., Guarracino, L., and Holliger, K., 2013, Seismic wave attenuation and dispersion due to wave-induced fluid flow in rocks with strong permeability fluctuations. The Journal of the Acoustical Society of America, 134, 4742–4751
| Seismic wave attenuation and dispersion due to wave-induced fluid flow in rocks with strong permeability fluctuations.Crossref | GoogleScholarGoogle Scholar |

Sams, M., Neep, J., Worthington, M., and King, M., 1997, The measurement of velocity dispersion and frequency-dependent intrinsic attenuation in sedimentary rocks: Geophysics, 62, 1456–1464
| The measurement of velocity dispersion and frequency-dependent intrinsic attenuation in sedimentary rocks:Crossref | GoogleScholarGoogle Scholar |

Sato, H., and Fehler, M., 1998, Seismic wave propagation and scattering in the heterogeneous earth: Springer-Verlag.

Sheriff, R. E., and Geldart, P. L., 1983, Exploration seismology, Vol. 2: Cambridge University Press.

Takeuchi, H., and Saito, M., 1972, Seismic surface waves, in B. A. Bolt, ed., Methods in computational physics: Academic Press, 11, 217–295.

Vogelaar, B., 2009, Fluid effect on wave propagation in heterogeneous porous media: Ph.D. thesis, Delft University of Technology.

Wentworth, C. K., 1922, A scale of grade and class terms for clastic sediments: The Journal of Geology, 30, 377–392
| A scale of grade and class terms for clastic sediments:Crossref | GoogleScholarGoogle Scholar |

Western Australia Planning Commission, 2001, Gandangara land use and water management strategy: Western Australia Planning Commission, Final Report, Perth, Western Australia.

Wilson, M. E., and Garcia, M. O., 2009, Sedimentology and aquifer quality of the Yarragadee Formation in the Perth Basin: Report for Department of Water, 120 pp.

Winkler, K. W., 1985, Dispersion analysis of velocity and attenuation in Berea sandstone: Journal of Geophysical Research, 90, 6793–6800
| Dispersion analysis of velocity and attenuation in Berea sandstone:Crossref | GoogleScholarGoogle Scholar |

Wu, X., and Nyland, E., 1987, Automated stratigraphic interpretation of well log data: Geophysics, 52, 1665–1676
| Automated stratigraphic interpretation of well log data:Crossref | GoogleScholarGoogle Scholar |

Zimmer, M. A., 2004, Seismic velocities in unconsolidated sands: measurements of pressure, sorting, and compaction effects: Ph.D. thesis, Stanford University.