Constraining properties of sedimentary strata using receiver functions: An example from the atlantic coastal plain of the southeastern United States

Erin Cunningham; Vedran Lekic

doi:10.1785/0120190191

Constraining properties of sedimentary strata using receiver functions: An example from the atlantic coastal plain of the southeastern United States

Erin Cunningham
, Vedran Lekic

Research output: Contribution to journal › Article › peer-review

22 Scopus citations

Abstract

Thickness and seismic velocities of sedimentary sequences strongly affect their response during earthquakes, which can prolong and amplify ground motions. We characterize shallow structure of Atlantic Coastal Plain (ACP) sediments using a passive-seismic approach based on high-frequency P-to-S receiver functions. We map the site-specific fundamental frequency for 64 USArray Transportable Array stations and confirm that the method yields results similar to those from traditional spectral ratio techniques, with fundamental frequencies between 0.1 and 1 Hz. In addition, using sediment S-wave reverberations and P-to-S phase arrival times measured directly from the receiver functions, we invert for average S-and P-wave velocity profiles of the ACP sedimentary strata.p We find that V_S increases with depth following a power-law relationship (V_S z) whereas the increase of V_P with depth is more difficult to constrain using converted wave methods; therefore, we choose to use the Brocher (2005) relationship to obtain V_P through a V_P = V_S relationship. Finally, we use the variation of measured S-reverberation amplitudes with depth to validate these velocity profiles. These results have implications for seismic shaking across the ACP, which covers large portions of the eastern United States.

Original language	English
Pages (from-to)	519-533
Number of pages	15
Journal	Bulletin of the Seismological Society of America
Volume	110
Issue number	2
DOIs	https://doi.org/10.1785/0120190191
State	Published - Apr 1 2020
Externally published	Yes

Funding

The authors would like to thank Martin Chapman, two anonymous reviewers, and Associate Editor Stefano Parolai for their comments and suggestions which greatly improved the article. The authors are especially grateful to Editor-in-Chief Thomas Pratt for his invaluable feedback and discussions which led to substantial improvements in the focus of this study. This work was supported by National Science Foundation (NSF) Grant CAREER EAR-1352214.

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title = "Constraining properties of sedimentary strata using receiver functions: An example from the atlantic coastal plain of the southeastern United States",

abstract = "Thickness and seismic velocities of sedimentary sequences strongly affect their response during earthquakes, which can prolong and amplify ground motions. We characterize shallow structure of Atlantic Coastal Plain (ACP) sediments using a passive-seismic approach based on high-frequency P-to-S receiver functions. We map the site-specific fundamental frequency for 64 USArray Transportable Array stations and confirm that the method yields results similar to those from traditional spectral ratio techniques, with fundamental frequencies between 0.1 and 1 Hz. In addition, using sediment S-wave reverberations and P-to-S phase arrival times measured directly from the receiver functions, we invert for average S-and P-wave velocity profiles of the ACP sedimentary strata.p We find that VS increases with depth following a power-law relationship (VS z) whereas the increase of VP with depth is more difficult to constrain using converted wave methods; therefore, we choose to use the Brocher (2005) relationship to obtain VP through a VP = VS relationship. Finally, we use the variation of measured S-reverberation amplitudes with depth to validate these velocity profiles. These results have implications for seismic shaking across the ACP, which covers large portions of the eastern United States.",

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N2 - Thickness and seismic velocities of sedimentary sequences strongly affect their response during earthquakes, which can prolong and amplify ground motions. We characterize shallow structure of Atlantic Coastal Plain (ACP) sediments using a passive-seismic approach based on high-frequency P-to-S receiver functions. We map the site-specific fundamental frequency for 64 USArray Transportable Array stations and confirm that the method yields results similar to those from traditional spectral ratio techniques, with fundamental frequencies between 0.1 and 1 Hz. In addition, using sediment S-wave reverberations and P-to-S phase arrival times measured directly from the receiver functions, we invert for average S-and P-wave velocity profiles of the ACP sedimentary strata.p We find that VS increases with depth following a power-law relationship (VS z) whereas the increase of VP with depth is more difficult to constrain using converted wave methods; therefore, we choose to use the Brocher (2005) relationship to obtain VP through a VP = VS relationship. Finally, we use the variation of measured S-reverberation amplitudes with depth to validate these velocity profiles. These results have implications for seismic shaking across the ACP, which covers large portions of the eastern United States.

AB - Thickness and seismic velocities of sedimentary sequences strongly affect their response during earthquakes, which can prolong and amplify ground motions. We characterize shallow structure of Atlantic Coastal Plain (ACP) sediments using a passive-seismic approach based on high-frequency P-to-S receiver functions. We map the site-specific fundamental frequency for 64 USArray Transportable Array stations and confirm that the method yields results similar to those from traditional spectral ratio techniques, with fundamental frequencies between 0.1 and 1 Hz. In addition, using sediment S-wave reverberations and P-to-S phase arrival times measured directly from the receiver functions, we invert for average S-and P-wave velocity profiles of the ACP sedimentary strata.p We find that VS increases with depth following a power-law relationship (VS z) whereas the increase of VP with depth is more difficult to constrain using converted wave methods; therefore, we choose to use the Brocher (2005) relationship to obtain VP through a VP = VS relationship. Finally, we use the variation of measured S-reverberation amplitudes with depth to validate these velocity profiles. These results have implications for seismic shaking across the ACP, which covers large portions of the eastern United States.

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Constraining properties of sedimentary strata using receiver functions: An example from the atlantic coastal plain of the southeastern United States

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