Quantification of Small-Scale Heterogeneity at the Core-Mantle Boundary Using Sample Entropy of SKS and SPdKS Synthetic Waveforms

Qualitative and quantitative analysis of seismic waveforms sensitive to the core-mantle boundary (CMB) region reveal the presence of ultralow-velocity zones (ULVZs) that have a strong decrease in compressional (P) and shear (S) wave velocity, and an increase in density within thin structures. However, understanding their physical origin and relation to the other large-scale structures in the lowermost mantle are limited due to an incomplete mapping of ULVZs at the CMB. The SKS and SPdKS seismic waveforms is routinely used to infer ULVZ presence, but has thus far only been used in a limited epicentral distance range. As the SKS/SPdKS wavefield interacts with a ULVZ it generates additional seismic arrivals, thus increasing the complexity of the recorded wavefield. Here, we explore utilization of the multi-scale sample entropy method to search for ULVZ structures. We investigate the feasibility of this approach through analysis of synthetic seismograms computed for PREM, 1-, 2.5-, and 3-D ULVZs as well as heterogeneous structures with a strong increase in velocity in the lowermost mantle in 1- and 2.5-D. We find that the sample entropy technique may be useful across a wide range of epicentral distances from 100 degrees to 130 degrees. Such an analysis, when applied to real waveforms, could provide coverage of roughly 85% by surface area of the CMB.

Automated summary

Qualitative and quantitative analysis of seismic waveforms can reveal the presence of ultralow-velocity zones (ULVZs) at the core-mantle boundary region, but the mapping of ULVZs is incomplete. Researchers have explored the use of multi-scale sample entropy method to search for ULVZ structures, and found this approach to be potentially effective across a wide range of epicentral distances.