<i>P</i> and <i>S</i> Wave Receiver Function Imaging of Subduction With Scattering Kernels

Hansen, S. M.; Schmandt, Brandon

doi:10.1002/2017gc007120

Cited by 31 publications

(55 citation statements)

References 80 publications

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“…Combining the information extracted from all the scattering modes by stacking the images linearly is an efficient tool to extract coherent information (Bostock et al, ; Hansen & Schmandt, ). In the case of GRT, the PS , PpS , and PsS modes are combined to create a composite result for δβ / β variations, and the PpP mode gives the result for the δα / α variations.…”

Section: Discussion: Advantages and Drawbacks Of The Methodsmentioning

confidence: 99%

“…Our method projects and stacks teleseismic waveform data in the depth domain to recover scattering structure. Other methods have the same basic principle, ranging from fast 1-D CCP stacking (Dueker & Sheehan, 1997) to 2-D multimode CCP (Tauzin et al, 2016) and 3-D prestack techniques (this paper; Hansen & Schmandt, 2017). All these methods afford very high spatial resolution corresponding to one wavelength for PS scattering and ∕2 for multiple modes, and prestack techniques are able to image structures as shallow as two times the interstation spacing down to approximately the same depth as the array aperture (Miller et al, 1987;Rondenay, 2009).…”

Section: Scattering Potential Versus Elastic Perturbationsmentioning

confidence: 99%

“…Their method was tested using 2.5‐D synthetic data obtained from ray tracing (Raysum, Frederiksen & Bostock, ), as well as data from the Cascadia93, Mendocino, and USArray experiments. A similar method based on sensitivity kernels for P ‐to‐ S and S ‐to‐ P conversions has been devised by Hansen and Schmandt () and tested using 2‐D synthetics obtained from spectral element simulations (Specfem2D; Tromp et al, ). Both methods have the same order of computational cost as 2‐D GRT and can image laterally varying structures such as subducting slabs given a dense ray coverage of the region of interest.…”

Section: Introductionmentioning

confidence: 99%

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Multimode 3‐D Kirchhoff Migration of Receiver Functions at Continental Scale

2019

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Receiver function analysis is widely used to image sharp structures in the Earth, such as the Moho or transition zone discontinuities. Standard procedures either rely on the assumption that underlying discontinuities are horizontal (common conversion point stacking) or are computationally expensive and usually limited to 2‐D geometries (reverse time migration and generalized Radon transform). Here, we develop a teleseismic imaging method that uses fast 3‐D traveltime calculations with minimal assumption about the underlying structure. This allows us to achieve high computational efficiency without limiting ourselves to 1‐D or 2‐D geometries. In our method, we apply acoustic Kirchhoff migration to transmitted and reflected teleseismic waves (i.e., receiver functions). The approach expands on the work of Cheng et al. (2016, https://doi.org/10.1093/gji/ggw062) to account for free surface multiples. We use an Eikonal solver based on the fast marching method to compute traveltimes for all scattered phases. Three‐dimensional scattering patterns are computed to correct the amplitudes and polarities of the three component input signals. We consider three different stacking methods (linear, phase weighted, and second root) to enhance the structures that are most coherent across scattering modes and find that second‐root stack is the most effective. Results from synthetic tests show that our imaging principle can recover scattering structures accurately with minimal artifacts. Application to real data from the Multidisciplinary Experiments for Dynamic Understanding of Subduction under the Aegean Sea experiment in the Hellenic subduction zone yields images that are similar to those obtained by 2‐D generalized Radon transform migration at no additional computational cost, further supporting the robustness of our approach.

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Section: Discussion: Advantages and Drawbacks Of The Methodsmentioning

confidence: 99%

Section: Scattering Potential Versus Elastic Perturbationsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Multimode 3‐D Kirchhoff Migration of Receiver Functions at Continental Scale

2019

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“…Under the Kirchoff migration framework, Cheng et al () proposed a method with 3‐D travel time calculations and 1‐D scattering coefficients and demonstrated resolution of dipping structures with correct polarities. Subsequently, Hansen and Schmandt () emphasized the advantages of applying multimode (Ps, Sp) scattering kernels with 3‐D travel times and scattering coefficients and tested the method with a subduction zone model. Here for the purpose of Ps scattered wave imaging at mantle transition zone depths on a continental scale, we implement a 3‐D migration framework that builds upon the approach of Cheng et al ().…”

Section: Methodsmentioning

confidence: 99%

Application of Ps Scattering Kernels to Imaging the Mantle Transition Zone With Receiver Functions

Zhang

Schmandt

2019

JGR Solid Earth

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Seismic imaging of the global boundaries of the mantle transition zone provides important constraints regarding mantle composition and convection. Additionally, modern hypotheses about mantle convection and increasing seismic data resources motivate attempts to image more complex regional transition zone structures such as dipping and discontinuous interfaces. Here we extend a 3-D prestack migration method to make it more applicable for transition zone imaging with Ps receiver functions. After validation with 1-D synthetic data, two types of hypothetical structures are adopted to demonstrate the strengths and weaknesses of different practical imaging parameters with 2-D synthetic tests. The results show that the method can resolve dipping anomalies and laterally discontinuous low velocity layers. However, receiver spacing of 0.5°is inadequate to accurately migrate scattering from all possible angles in the transition zone at~0.3 Hz. Application of a slowness cutoff window about the Ps raypath can mitigate artifacts due to low receiver density, but the tradeoff is a decrease in the maximum resolvable dip angle. Further synthetic tests evaluate source wavelet effects, addition of observed seismic noise to synthetic data, and imaging grid dimensions. Cumulatively, the tests indicate that generic application of migration algorithms to the limited source-receiver distributions relevant for the transition zone should be treated cautiously. Imaging parameters, such as the slowness cutoff and wavelet, should be chosen based on synthetic tests for hypothetical targets and realistic source-receiver geometries. Finally, observational Ps receiver functions from the USArray are migrated with the new method.Plain Language Summary This study extends a seismic imaging method to make it more applicable to the mantle transition zone depths (from 300 to 800 km) because seismic imaging of sharply defined structures in this layer of Earth provide important insights into mantle composition and convection. The method was tested with realistic combinations of synthetic earthquake sources and seismic network densities to evaluate how it would perform for hypothetical transition zone structures. The results are encouraging in that they show the possibility of detecting increasingly complex structures in this layer of Earth's interior, but they also show that realistic combinations of earthquakes and seismographs present challenges for generic application of imaging methods to the transition zone. Examples from a suite of synthetic tests outline how the new imaging method may be optimized to resolve some complex structures with realistic seismic data resources and avoid introducing artificial features that could confound structural interpretations.

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“…Alternatively, elastic RTM has been formulated for imaging specular reflectors using converted teleseismic waves from passive sources as described by Brytik et al (), Shang et al (), Hansen and Schmandt (), and Li et al () and related inverse scattering methods (e.g., Bostock et al, ; Poppeliers & Pavlis, ). These methods are based on back propagation using the elastic wave equation and involve the cross‐correlation of time‐reversed converted waves, that is, converted P to S , with time‐reversed transmitted waves, that is, direct P .…”

Section: Introductionmentioning

confidence: 99%

Surface Imaging Functions for Elastic Reverse Time Migration

Pollitz

2019

JGR Solid Earth

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Reverse time migration is often used to interpret acoustic or three‐component seismic recordings by creating an image of subsurface seismic reflectors. Here I describe elastic reverse time migration imaging functions that are cast as waveform misfit sensitivity kernels of contrasts in material parameters across hypothetical seismic discontinuities, that is, specular reflectors. The proposed “surface” imaging functions are theoretically applicable to either reflected or converted waves in order to estimate the location and reflectivity of these discontinuities. The surface imaging functions, as well as volumetric sensitivity kernels that target point diffractors, are tested on sets of synthetic surface array recordings that sample the 3‐D seismic wavefield on simple 2‐D structures generated using a 2.5‐D spectral element method. These tests illustrate that in contrast with the volumetric sensitivity kernels, the reflectivity is generally dominated by a high‐amplitude peak that coincides with input locations of discontinuities. Passive recordings of microseismicity, shot gathers, or a combination thereof can be potentially interpreted with the new surface imaging functions to yield useful reflectivity images.

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P and S Wave Receiver Function Imaging of Subduction With Scattering Kernels

Cited by 31 publications

References 80 publications

Multimode 3‐D Kirchhoff Migration of Receiver Functions at Continental Scale

Multimode 3‐D Kirchhoff Migration of Receiver Functions at Continental Scale

Application of Ps Scattering Kernels to Imaging the Mantle Transition Zone With Receiver Functions

Surface Imaging Functions for Elastic Reverse Time Migration

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