Role of Saturation on Elastic Dispersion and Attenuation of Tight Rocks: An Experimental Study

The fractal texture (or fabric) of porous media, which supports fluid flow at different scales, is the main cause of wave anelasticity (dispersion and attenuation) on a wide range of frequencies. To model this phenomenon, we develop a theory of wave propagation in a fluid saturated infinituple‐porosity media containing inclusions at multiple scales, based on the differential effective medium (DEM) theory of solid composites and Biot‐Rayleigh theory for double‐porosity media. The dynamical equations are derived from first principles, that is, based on the strain (potential), kinetic, and dissipation energies, leading to generalized stiffness and density coefficients. The scale of the inclusions can be characterized by different distributions. The theory shows that the anelasticity depends on the size (radius) of the inclusions, parameter θ (exponential distribution), mean radius r0 and variance σr2 (Gaussian distribution) and the fractal dimension Df (self‐similar distribution). When Df = 2, θ = 1 and σr2 = 4, the three distributions give the same P‐wave velocities and attenuation, since each added inclusion phase has nearly the same volume fraction. For the modeling results, the range of anelasticity of Df = 2.99/θ = 1/σr2 = 4 is broader than that of Df < 2.99/θ < 1/σr2 < 4. To confirm the validity of the model, we compare the results with laboratory measurements on tight sandstone and carbonate samples in the range 1 Hz–1 kHz, Fox Hill sandstone (5 Hz–800 kHz) and field measurements of marine sediments (50 Hz–400 kHz). This comparison shows that the model successfully describes the observed anelasticity.

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“…The measured data can be found in Li et al. (2020), Batzle et al. (2006), and Zhou et al.…”

Section: Data Availability Statementmentioning

confidence: 93%

Wave Propagation in Infinituple‐Porosity Media

Zhang

Carcione

2021

JGR Solid Earth

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“…Ren et al ., 2009; Quintal et al ., 2011a; Zhao et al ., 2015, 2017; He et al ., 2018, 2020) and also using laboratory experiments (e.g. Batzle et al ., 2006; Bouzidi and Schmitt, 2006; Yin et al ., 2017; Li et al ., 2020a and 2020b).…”

Section: Introductionmentioning

confidence: 99%

Analysis of the frequency dependence characteristics of wave attenuation and velocity dispersion using a poroelastic model with mesoscopic and microscopic heterogeneities

Wang

Sun

et al. 2021

Geophysical Prospecting

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Seismic waves passing through partially saturated porous rocks produce pressure gradients in the fluid phase, and, hence, the resulting fluid flow is accompanied by various length scales. The major mechanism responsible for seismic attenuation and dispersion is arguably known as wave‐induced fluid flow between inhomogeneities of microscopic, mesoscopic and macroscopic scales. Previous studies have revealed that differentiating the influence of heterogeneities at various scales on wave attenuation within seismic exploration and sonic frequencies, nevertheless, is very difficult. This is because wave attenuation mechanisms due to different heterogeneities are practically impossible to be unrelated. Therefore, it is important for a more quantitative interpretation of the relative contribution of inter‐dependent energy loss mechanisms through improved understanding of the combined influences associated to the microscopic squirt flow and mesoscopic fluid flow. We introduce a scaled poroelastic model to evaluate frequency‐dependent attenuation and velocity dispersion characteristics by considering the combined presence of microscopic and mesoscopic heterogeneities. To do so, the capillarity effects are incorporated into the poroelastic model with random distributions of the sizes of mesoscopic‐scale heterogeneities. A range of pertinent scenarios are calculated, and the acoustic properties indicate wave attenuation decreases whereas the phase velocity increases corresponding to additional capillary forces. Meanwhile, numerical results of the proposed model were compared with experimental measurements of a tight sandstone to examine its validity. Results of numerical simulations suggest that seismic reflections produce more complicated signatures in the presence of an interbedded structure of a reservoir exhibiting velocity dispersion. Therefore, the proposed procedure can help in assessing the sensitivities of frequency‐dependent seismic signatures to reservoir fluid mobility and patch heterogeneities.

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“…Porous rocks are normally saturated with multiphase fluids underground (Zhao et al, 2017;Li et al, 2020a). When seismic waves passing through such subsurface rocks, it is unavoidable to create dissipative and dispersive responses.…”

Section: Introductionmentioning

confidence: 99%

“…Consequently, efforts must be made to precisely measure the dispersion and attenuation at seismic frequency bands and under varying physical conditions. Due to the high requirement of precision and the complexity of laboratory measurements, there are limited teams capable of conducting low-frequency measurements so far (Spencer, 1981;Batzle et al, 2006;Tisato and Quintal, 2013;Pimienta et al, 2015Pimienta et al, , 2019Mikhaltsevitch et al, 2016;Li et al, 2020a). The most prospecting method in low-frequency measurements is the forced-oscillation technique, allowing measurements over a wide frequency range and under varying physical conditions.…”

Section: Introductionmentioning

confidence: 99%

Combined effects of permeability and ﬂuid saturation on seismic wave dispersion and attenuation in partially-saturated sandstone

Wei

Wang

Han

et al. 2021

Adv. Geo-Energy Res.

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Knowledge of dispersion and attenuation is essential for better reservoir characterization and hydrocarbon identification. However, limited by reliable laboratory data at seismic frequency bands, the roles of rock and fluid properties in inducing dispersion and attenuation are still poorly understood. Here we perform a series of laboratory measurements on two sandstones under both dry and partially water-saturated conditions at frequencies ranging from 2 to 600 Hz. Two samples, Bentheimer and Bandera sandstones, have similar porosity of ∼20% but different permeability of 1830 mD and 33 mD. At vacuum-dry conditions, the bulk dispersion and attenuation in Bandera sandstone with more clay contents are distinctly larger than those in Bentheimer sandstone, suggesting clay contents might contribute to the inelasticity of the rock frame. The partially water-saturated results show the combined effects of rock permeability and fluid saturation on bulk dispersion and attenuation. Because of the high compressibility of gas, even a few percent of gas (∼5%) can substantially dominate the pore-fluid relaxation by providing a quick and short communication path for pore pressure gradients. The consequent bulk dispersion and attenuation are negligible. However, when the sample is approaching a fully water-saturated condition (gas saturation <5%), the gas effect gradually decreases. Instead, the rock permeability begins to play an essential role in the pore-fluid relaxation. For Bandera sandstone with lower permeability, a partially relaxed status of pore fluids is achieved when the gas saturation is lower than 5%, accompanied by significant attenuation and dispersion.

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Role of Saturation on Elastic Dispersion and Attenuation of Tight Rocks: An Experimental Study

Cited by 32 publications

References 62 publications

Wave Propagation in Infinituple‐Porosity Media

Wave Propagation in Infinituple‐Porosity Media

Analysis of the frequency dependence characteristics of wave attenuation and velocity dispersion using a poroelastic model with mesoscopic and microscopic heterogeneities

Combined effects of permeability and ﬂuid saturation on seismic wave dispersion and attenuation in partially-saturated sandstone

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