Equivalent near-field corner frequency analysis of 3D dynamic rupture simulations reveals source complexity

Abstract

Dynamic rupture simulations generate synthetic waveforms that account for non-linear source, path, and site complexity. Here, we analyze millions of spatially dense waveforms from 3D dynamic rupture simulations in a novel way to illuminate the spectral fingerprints of earthquake physics. We define a Brune-type equivalent near-field corner frequency (fc) to analyze the spatial variability of ground motion spectra and unravel their link to source complexity. We first investigate a simple 3D strike-slip setup, including an asperity and a barrier, and illustrate basic relations between source properties and fc variations. Next, we analyze > 13,000,000 synthetic near-field strong motion waveforms generated in three high-resolution dynamic rupture simulations of real earthquakes, namely, the Mw 7.1 2019 Ridgecrest mainshock, the Mw 6.4 Searles Valley foreshock, and the Mw 7.3 1992 Landers earthquake. All scenarios consider 3D fault geometries, topography, off-fault plasticity, viscoelastic attenuation, 3D velocity structure, and resolve frequencies up to 1-2 Hz. Our analysis reveals pronounced and localized patterns of elevated fc, specifically in the vertical components. We validate such fc variability in observed near-fault spectra. Using isochrone analysis, we identify the complex dynamic mechanisms that explain the rays of elevated fc and cause unexpectedly impulsive, localized, vertical ground motions. While the vertical high frequencies are also associated with path effects, rupture directivity, and coalescence of multiple rupture fronts, we show that they are dominantly caused by rake-rotated surface-breaking rupture fronts that decelerate due to fault heterogeneities or geometric complexity. Our findings highlight the potential of spatially dense ground motion observations for furthering our understanding of earthquake physics directly from near-field data.