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Volume 52, Issue 4
  • E-ISSN: 1365-2478

Abstract

ABSTRACT

A series of time‐lapse seismic cross‐well and single‐well experiments were conducted in a diatomite reservoir to monitor the injection of CO into a hydrofracture zone, based on P‐ and S‐wave data. A high‐frequency piezo‐electric P‐wave source and an orbital‐vibrator S‐wave source were used to generate waves that were recorded by hydrophones as well as 3‐component geophones. During the first phase the set of seismic experiments was conducted after the injection of water into the hydrofractured zone. The set of seismic experiments was repeated after a time period of seven months during which CO was injected into the hydrofractured zone. The questions to be answered ranged from the detectability of the geological structure in the diatomic reservoir to the detectability of CO within the hydrofracture. Furthermore, it was intended to determine which experiment (cross‐well or single‐well) is best suited to resolve these features.

During the pre‐injection experiment, the P‐wave velocities exhibited relatively low values between 1700 and 1900 m/s, which decreased to 1600–1800 m/s during the post‐injection phase (−5%). The analysis of the pre‐injection S‐wave data revealed slow S‐wave velocities between 600 and 800 m/s, while the post‐injection data revealed velocities between 500 and 700 m/s (−6%). These velocity estimates produced high Poisson's ratios between 0.36 and 0.46 for this highly porous (∼50%) material. Differencing post‐ and pre‐injection data revealed an increase in Poisson's ratio of up to 5%. Both velocity and Poisson's ratio estimates indicate the dissolution of CO in the liquid phase of the reservoir accompanied by an increase in pore pressure.

The single‐well data supported the findings of the cross‐well experiments. P‐ and S‐wave velocities as well as Poisson's ratios were comparable to the estimates of the cross‐well data.

The cross‐well experiment did not detect the presence of the hydrofracture but appeared to be sensitive to overall changes in the reservoir and possibly the presence of a fault. In contrast, the single‐well reflection data revealed an arrival that could indicate the presence of the hydrofracture between the source and receiver wells, while it did not detect the presence of the fault, possibly due to out‐of‐plane reflections.

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2004-06-11
2024-04-19

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References

  1. BilodeauB.J.1995. Determining water saturation in diatomite using wireline logs, Lost Hills Field, California. Proceedings of the SPE/AAPG Western Regional Meeting SPE 29653, 369–382.
  2. BourbieT., CoussyO. and ZinsznerB.1987. Acoustics of Porous Media . Gulf Publishing Co., Houston .
    [Google Scholar]
  3. DaleyT.M. and CoxD.2001. Orbital vibrator seismic source for simultaneous P‐ and S‐wave cross well acquisition. Geophysics66, 1471–1480.
    [Google Scholar]
  4. DaleyT.M., GrittoR., MajerE.L. and WestP.2003a. Tube‐wave suppression in single‐well seismic acquisition. Geophysics68, 863–869.
    [Google Scholar]
  5. DaleyT.M., GrittoR. and MajerE.L.2003b. Single well seismic imaging of a gas‐filled hydrofracture . Lawrence Berkeley National Laboratory Report, LBNL‐53601.
    [Google Scholar]
  6. DetournayE. and ChengH.1993. A short course on poroelasticity in rock mechanics: constitutive equations – theoretical background. Proceedings of the 34th U.S. Rock Mechanics Symposium , pp. 1–28.
  7. DvorkinJ., MavkoG. and NurA.1999. Overpressure detection from compressional‐ and shear‐wave data. Geophysical Research Letters26, 3417–3420.
    [Google Scholar]
  8. DvorkinJ. and NurA.1996. Elasticity of high‐porous sandstones: Theory for two North Sea data sets. Geophysics61, 1363–1370.
    [Google Scholar]
  9. GrahamS.A. and WilliamsL.A.1985. Tectonic, depositional and diagenetic history of Monterey formation (Miocene), central San Joaquin basin , California . AAPG Bulletin 69, 385–411.
    [Google Scholar]
  10. HoverstenG.M., GrittoR., WashbourneJ. and DaleyT.M.2003. CO2 gas/oil ratio prediction in a multi‐component reservoir by combined seismic and electromagnetic imaging. Geophysics68, 1580–1591.
    [Google Scholar]
  11. IsaacsC.M.1982. Influence of rock composition on the kinetics of silica phase changes in the Monterey Formation, Santa Barbara area, California. Geology10, 304.
    [Google Scholar]
  12. MajerE.L., PetersonJ.E., DaleyT.M., KaelinB., QueenJ., D'OnfroP. and RizerW.1997. Fracture detection using cross well and single well surveys. Geophysics62, 495–504.
    [Google Scholar]
  13. MallickS.2001. AVO and elastic impedance. The Leading Edge20, 1094–1104.
    [Google Scholar]
  14. MeredithJ.A., ToksözM.N. and ChengC.H.1993. Secondary shear waves from source boreholes. Geophysical Prospecting41, 287–312.
    [Google Scholar]
  15. PerriP.A., EmanueleM.A., FongW.S. and MoreaM.F.2000. Lost Hills CO2 pilot: evaluation, design, injectivity test results and implementation. Proceedings of the SPE/AAPG Western Regional Meeting SPE 62526, 13.
  16. PetersonJ.E., PaulsonB.N. and McEvillyT.V.1985. Applications of algebraic reconstruction techniques to cross hole seismic data. Geophysics50, 1566–1580.
    [Google Scholar]
  17. SimpsonG.2001. Influence of compression‐induced fluid pressures on rock strength in the brittle crust. Journal of Geophysical Research106(B9), 19465–19478.
    [Google Scholar]
  18. WangZ., CatesM.E. and LanganR.T.1998. Seismic monitoring of a CO2 flood in a carbonate reservoir: a rock physics study. Geophysics63, 1604–1617.
    [Google Scholar]
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Joint cross‐well and single‐well seismic studies of CO2 injection in an oil reservoir
Geophysical Prospecting 52, 323 (2004); https://doi.org/10.1111/j.1365-2478.2004.00418.x
/content/journals/10.1111/j.1365-2478.2004.00418.x
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