Publication Date:
2019-11-02
Description:
GRACE satellites have detected regionalscale preseismic, coseismic, and postseismic gravity changes associated with great earthquakes during the GRACE era (20022017). Earthquakes also excite globalscale transient gravity changes associated with free oscillations that may be discerned for a few days. In this study, we examine such global gravity changes due to Earth's free oscillations and quantify how they affect GRACE measurements. We employ the normal mode formalism to synthesize the global gravity changes after the 2004 Sumatra earthquake and simulate the (gravitational) free oscillation signals manifested in the GRACE Kband ranging (KBR) measurements. Using the Kaula orbit perturbation theory, we show how GRACE intersatellite distances are perturbed through a complex coupling of eigenfrequencies of the normal modes with the Earth's rotation rate and the GRACE satellites' orbital frequency. It is found that a few gravest normal modes can generate rangerate perturbations as large as 0.2 m/s, which are comparable to actual errors of GRACE KBR ranging and accelerometer instruments. Wavelet timefrequency analysis of the GRACE KBR residual data in December 2004 reveals the existence of a significant transient signal after the 2004 Sumatra earthquake. This transient signal is characterized by a frequency of ~0.022 mHz that could be potentially associated with the largest excitation due to the football mode of the Earth's free oscillation. However, the results are also affected by lowfrequency noise of the GRACE accelerometers. Improved spaceborne gravitational instrumentation may open new opportunities to study the Earth's interior and earthquakes independently from global seismological analysis.
Keywords:
Geosciences (General)
Type:
GSFC-E-DAA-TN74011
,
Journal of Geophysical Research. Solid Earth (ISSN 2169-9356) (e-ISSN 2169-9313); 124; 7; 7483-7503
Format:
application/pdf
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