Effects of fluids and dual-pore systems on pressure-dependent velocities and attenuations in carbonates
Agersborg, Remy; Johansen, Tor Arne; Jakobsen, Morten; Sothcott, Jeremy; Best, Angus ORCID: https://orcid.org/0000-0001-9558-4261. 2008 Effects of fluids and dual-pore systems on pressure-dependent velocities and attenuations in carbonates. Geophysics, 73 (5). N35-N47. 10.1190/1.2969774
Full text not available from this repository.Abstract/Summary
The effects of fluid substitution on P- and S-wave velocities in carbonates of complex texture are still not understood fully. The often-used Gassmann equation gives ambiguous results when compared with ultrasonic velocity data. We present theoretical modeling of velocity and attenuation measurements obtained at a frequency of 750 kHz for six carbonate samples composed of calcite and saturated with air, brine, and kerosene. Although porosities (2%–14%) and permeabilities (0–74 mD) are relatively low, velocity variations are large. Differences between the highest and lowest P- and S-wave velocities are about 18% and 27% for brine-saturated samples at 60 and 10 MPa effective pressure, respectively. S-wave velocities are measured for two orthogonal polarizations; for four of six samples, anisotropy is revealed. TheGassmann model underpredicts fluid-substitution effects by <2% for three samples and by as much as 5% for the rest of the six samples. Moreover, when dried, they also show decreasing attenuation with increasing confining pressure. To model this behavior, we examine a pore model made of two pore systems: one constitutes the main and drainable porosity, and the other is made of undrained cracklike pores that can be associated with grain-to-grain contacts. In addition, these dried rock samples are modeled to contain a fluid-filled-pore system of grain-to-grain contacts, potentially causing local fluid flow and attenuation. For the theoretical model, we use an inclusion model based on the T-matrix approach, which also considers effects of pore texture and geometry, and pore fluid, global- and local-fluid flow. By using a dual-pore system, we establish a realistic physical model consistently describing the measured data.
Item Type: | Publication - Article |
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Digital Object Identifier (DOI): | 10.1190/1.2969774 |
ISSN: | 0016-8033 |
Date made live: | 24 Nov 2008 +0 (UTC) |
URI: | https://nora.nerc.ac.uk/id/eprint/164008 |
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