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The Impact of Plate Motions on Long‐Wavelength InSAR‐Derived Velocity Fields

Oliver L. Stephenson, Yuan‐Kai Liu, Zhang Yunjun, M. Simons, P. A. Rosen, Xiaohua Xu

2022Geophysical Research Letters49 citationsDOIOpen Access PDF

Abstract

Abstract Interferometric Synthetic Aperture Radar (InSAR) measurements are increasingly being used to measure small amplitude tectonic deformations over large spatial scales. Residual signals are often present at these scales and are interpreted to be noise of indeterminate origin, limiting studies of long‐wavelength deformation. Here, we demonstrate the impact of rigid motion by the Earth's tectonic plates on velocity fields derived from InSAR. The range‐dependent incidence angle of the InSAR observations, coupled with plate velocities of centimeters per year, can induce long‐wavelength spatial gradients of millimeters per year over hundreds of kilometers in InSAR velocity fields. We show that, after applying corrections, including for the ionosphere and troposphere, plate motion represents the dominant source of long‐wavelength secular velocity gradients in multi‐year time series for several study areas. This signal can be accounted for using plate motion models, allowing improved detection of regional tectonic strain at continental scales.

Topics & Concepts

Interferometric synthetic aperture radarGeologyGeodesyWavelengthRadarInterferometrySynthetic aperture radarAmplitudeTectonicsGeophysicsSeismologyRemote sensingOpticsPhysicsTelecommunicationsComputer scienceearthquake and tectonic studiesSynthetic Aperture Radar (SAR) Applications and TechniquesEarthquake Detection and Analysis
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