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.
CITATION STYLE
Zhang, H., & Schmandt, B. (2019). Application of Ps Scattering Kernels to Imaging the Mantle Transition Zone With Receiver Functions. Journal of Geophysical Research: Solid Earth, 124(1), 709–728. https://doi.org/10.1029/2018JB016274
Mendeley helps you to discover research relevant for your work.