Earthquake Detectability and Depth Resolution with Dense Arrays in Long Beach, California: Further Evidence for Upper-Mantle Seismicity within a Continental Setting
Abstract
The Newport–Inglewood fault (NIF) is a slowly deforming fault cutting through a thin continental crust with a normal geothermal; yet it hosts some of the deepest earthquakes in southern California. The nucleation of deep earthquakes in such a continental setting is not well understood. Moreover, the deep seismogenic zone implies that the maximum NIF earthquake magnitude may be larger than expected. Here, we quantify the resolution of the Long Beach (LB) and the Extended Long Beach (ELB) dense arrays used to study deep NIF seismicity. Previous study of the regional catalog and of downward‐continued LB array data found NIF seismicity extending into the upper mantle beneath LB. Later studies, which analyzed the ELB raw data, found little evidence for such deep events. To resolve this inconsistency, we quantify the array’s microearthquake detectability and resolution power via analysis of pre‐ and postdownward migrated LB seismograms and benchmark tests. Downward migration focuses energy onto the source region and deamplifies the surface noise, thus significantly improving detectability and resolution. The detectability is also improved with the increase in the array aperture‐to‐source‐depth ratio. The LB array maximum aperture is only 20% larger than the ELB aperture, yet its resolution for deep (>20 km) events is improved by about a factor of two, suggesting that small changes to the array geometry may yield significant improvement to the resolution power. Assuming a constant aperture, we find the LB array maintain resolution with 1% of its sensors used for backprojection. However, the high‐sensor density is essential for improving the signal‐to‐noise ratio. Analysis of the regional and array‐derived NIF catalogs together with newly acquired Moho depths beneath the NIF suggests that mantle seismicity beneath LB may be a long‐lived feature of this fault.
Copyright and License
© 2024 Seismological Society of America.
Acknowledgement
The authors thank three anonymous reviewers and the associate editor for providing constructive remarks that greatly improved the quality of this article. This research was supported by the Israeli Science Foundation Grant Number 1802/22.
Data Availability
The Southern California Earthquake Data Center earthquake catalog is available at https://scedc.caltech.edu (last accessed January 2021). The Long Beach (LB) seismicity catalog is from Inbal et al. (2016), and the Extended Long Beach (ELB) seismicity catalog is from Yang et al. (2021). The raw LB data are protected by a license agreement with Signal Hill Petroleum and will be provided by the authors upon request. The supplemental material includes Figures S1–S5.
Conflict of Interest
The authors acknowledge that there are no conflicts of interest recorded.
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Additional details
- ISSN
- 1938-2057
- Israel Science Foundation
- 1802/22
- Caltech groups
- Division of Geological and Planetary Sciences, Seismological Laboratory