When do fractured media become seismically anisotropic? Some implications on quantifying fracture properties

Yousef, B.M.; Angus, D.A.

doi:10.1016/j.epsl.2016.03.040

Cited by 22 publications

(14 citation statements)

References 48 publications

(78 reference statements)

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“…Some authors argue that it is not possible to distinguish TTI from VTI in real experimental cases without a priori information (Bakulin et al, 2009). Assuming the most general anisotropic media has also become rather usual, in particular with the improvement of computational resources, allowing for a more detailed and complex reconstruction of the subsurface physical properties (e.g., Zhou and Greenhalgh, 2005), although successful field data applications are yet to be achieved to Figure 3. For both selected meridians, 0 rad and π/4 rad azimuths, relative travel-time errors in percentage with respect to the analytic value for each of the four simulations used in the sensitivity analysis.…”

Section: Anisotropy In Seismic Inversion Methodsmentioning

confidence: 99%

“…Anisotropy is a multiscale phenomenon, and its causes are diverse. In the crust, it can be produced by the preferred orientation of mineral grains or their crystal axes (Schulte-Pelkum and Mahan, 2014; Almqvist and Mainprice, 2017), the alignment of cracks and fracture networks and the presence of fluids (Crampin, 1981;Maultzsch et al, 2003;Yousef and Angus, 2016), or the bedding of layers much thinner than the wavelength used to explore them (Backus, 1962;Johnston and Christensen, 1995;Sayers, 2005). In the mantle, anisotropy is related to the alignment of olivine crystals due to mantle flow (Nicolas and Christensen, 1987;Montagner et al, 2007), aligned melt inclusions (Holtzman et al, 2003;Kendall et al, 2005), large-scale deformation (Vinnik et al, 1992;Vauchez et al, 2000) and preexisting lithospheric fabric (Kendall et al, 2006), among others.…”

Section: Introductionmentioning

confidence: 99%

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Anisotropic P-wave travel-time tomography implementing Thomsen's weak approximation in TOMO3D

Meléndez¹,

Tejero²,

Sallarès³

et al. 2019

Solid Earth

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Abstract. We present the implementation of Thomsen's weak anisotropy approximation for vertical transverse isotropy (VTI) media within TOMO3D, our code for 2-D and 3-D joint refraction and reflection travel-time tomographic inversion. In addition to the inversion of seismic P-wave velocity and reflector depth, the code can now retrieve models of Thomsen's parameters (δ and ε). Here, we test this new implementation following four different strategies on a canonical synthetic experiment in ideal conditions with the purpose of estimating the maximum capabilities and potential weak points of our modeling tool and strategies. First, we study the sensitivity of travel times to the presence of a 25 % anomaly in each of the parameters. Next, we invert for two combinations of parameters (v, δ, ε and v, δ, v⊥), following two inversion strategies, simultaneous and sequential, and compare the results to study their performance and discuss their advantages and disadvantages. Simultaneous inversion is the preferred strategy and the parameter combination (v, δ, ε) produces the best overall results. The only advantage of the parameter combination (v, δ, v⊥) is a better recovery of the magnitude of v. In each case, we derive the fourth parameter from the equation relating ε, v⊥ and v. Recovery of v, ε and v⊥ is satisfactory, whereas δ proves to be impossible to recover even in the most favorable scenario. However, this does not hinder the recovery of the other parameters, and we show that it is still possible to obtain a rough approximation of the δ distribution in the medium by sampling a reasonable range of homogeneous initial δ models and averaging the final δ models that are satisfactory in terms of data fit.

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Section: Anisotropy In Seismic Inversion Methodsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Anisotropic P-wave travel-time tomography implementing Thomsen's weak approximation in TOMO3D

Meléndez¹,

Tejero²,

Sallarès³

et al. 2019

Solid Earth

View full text Add to dashboard Cite

show abstract

“…Anisotropy is a multiscale phenomenon, and its causes are diverse. In the crust, it can be produced by the preferred orientation of mineral grains or their crystal axes (Schulte-Pelkum and Mahan, 2014;Almqvist and Mainprice, 2017), the alignment of cracks and fracture networks and the presence of fluids (Crampin, 1981;Maultzsch et al, 2003;Yousef and Angus, 2016), or the bedding of layers much thinner than the wavelength used to explore them (Backus, 1962;Johnston and Christensen, 1995;Sayers, 2005). In the mantle, anisotropy is related to the alignment of olivine crystals due to mantle flow (Nicolas and Christensen, 1987;Montagner et al, 2007), aligned melt inclusions (Holtzman et al, 2003;Kendall et al, 2005), large-scale deformation (Vinnik et al, 1992;Vauchez et al, 2000), and preexisting lithospheric fabric (Kendall et al, 2006), among others.…”

Section: Introductionmentioning

confidence: 99%

Anisotropic P-wave traveltime tomography implementing Thomsen's weak approximation in TOMO3D

Meléndez¹,

Jiménez²,

Sallarès³

et al. 2019

Preprint

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Abstract. We present the implementation of Thomsen's weak anisotropy approximation for VTI media within TOMO3D, our code for 2-D and 3-D joint refraction and reflection traveltime tomographic inversion. In addition to the inversion of seismic P-wave velocity and reflector depth, the code can now retrieve models of the Thomsen's parameters δ and ε. Here we test this new implementation following four different strategies on a canonical synthetic experiment. First, we study the sensitivity of traveltimes to the presence of a 25 % anomaly in each of the parameters. Next, we invert for two combinations of parameters, (v, δ, ε) and (v, δ, v⟂), following two inversion strategies, simultaneous and sequential, and compare the results to study their performances and discuss their advantages and disadvantages. Simultaneous inversion is the preferred strategy and the parameter combination (v, δ, ε) produces the best overall results. The only advantage of the parameter combination (v, δ, v⟂) is a better recovery of the magnitude of v. In each case we derive the fourth parameter from the equation relating ε, v⟂ and v. Recovery of v, ε and v⟂ is satisfactory whereas δ proves to be impossible to recover even in the most favorable scenario. However, this does not hinder the recovery of the other parameters, and we show that it is still possible to obtain a rough approximation of δ distribution in the medium by sampling a reasonable range of homogeneous initial δ models and averaging the final δ models that are satisfactory in terms of data fit.

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“…Many, if not most, rocks and rock masses are elastically anisotropic with respect to the propagation direction of seismic waves. Observations of seismic anisotropy inform us about in situ metamorphic strain textures (e.g., Almqvist et al, 2010;Godfrey et al, 2000;Ji et al, 2013;Kern & Wenk, 1990;Mainprice & Nicolas, 1989), layering (e.g., Backus, 1962;Brown et al, 1991;Grech et al, 2002;Kebaili & Schmitt, 1997), and properties of the natural and induced fracture's network (e.g., Grechka & Tsvankin, 2004;Nakagawa et al, 2003;Sayers & Kachanov, 1995;Yousef & Angus, 2016). This information is a key to understanding in situ geological structures and processes, but properly obtaining it requires knowledge of the seismic wavefield behavior in anisotropic media that are addressed here both experimentally and numerically.…”

Section: Introductionmentioning

confidence: 99%

Acoustic Reflectivity From Variously Oriented Orthorhombic Media: Analogies to Seismic Responses From a Fractured Anisotropic Crust

Malehmir

Schmitt

2017

JGR Solid Earth

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The variations in the strength of seismic reflections with both angles of incidence and azimuth are being used to constrain the orientations and degrees of mechanical anisotropy of geological formations. This information is often used in turn to infer the directions of fracturing and stress usually assuming simplified geological structures that in many cases are not realistic. In order to further understand this problem, the reflectivities from a set of variously titled samples cut from a single block of a common anisotropic composite material are measured with both angles of incidence and azimuth in the laboratory. Each sample is analogous to a formation in which the fracture sets increasingly dip. The observed responses differ from plane wave theory due to the finite nature of the experiment. However, the deviations are well accounted for by modeling the acoustic reflectivity using its bounded pulse. As expected, the reflectivities vary with the sample tilt, the angle of incidence, and the azimuth at which the measurements are made. However, some of these responses, such as the precritical reflectivities, do not appear to strongly vary with azimuth for a given sample. Critical angle phenomena, too, must be used cautiously as the observed reflectivity peaks do not lie at the exact critical angle. These results suggest that reflectivities could be an important source of information with regard to the spatial orientation of anisotropic layer.

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When do fractured media become seismically anisotropic? Some implications on quantifying fracture properties

Cited by 22 publications

References 48 publications

Anisotropic P-wave travel-time tomography implementing Thomsen's weak approximation in TOMO3D

Anisotropic P-wave travel-time tomography implementing Thomsen's weak approximation in TOMO3D

Anisotropic P-wave traveltime tomography implementing Thomsen's weak approximation in TOMO3D

Acoustic Reflectivity From Variously Oriented Orthorhombic Media: Analogies to Seismic Responses From a Fractured Anisotropic Crust

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