Effects of Willamette Valley Sedimentary Structure on Ground Motions
Loading...
Date
2025-02-24
Authors
Shimony, Roey
Journal Title
Journal ISSN
Volume Title
Publisher
University of Oregon
Abstract
Accurately estimating ground motions is critical for seismic hazard assessments, particularly in regions like the Cascadia Subduction Zone (CSZ), which has the potential to generate M8-9 megathrust earthquakes. This study focuses on the Willamette Valley (WV), an elongated sedimentary structure extending from Eugene to Portland, Oregon, which has been understudied despite being home to most of Oregon’s population and infrastructure. The WV is characterized by soft, low-density sediments confined between two mountain ranges, the Oregon Coast Range and the Cascade Range, creating significant lateral contrasts in seismic velocity. Using available geologic, geophysical, and structural data, we constructed new velocity models of the WV basin, varying the basin’s depth geometry and seismic velocity structure. To test these models, we performed numerical simulations of three M~4 local crustal earthquakes, and compared our synthetic ground motions with recorded data. Our findings indicate that the sedimentary structure of the WV plays a significant role in amplifying ground motions from local earthquakes. This has important implications for seismic hazard assessments in the region, and highlights the need for a detailed representation of the WV’s shallow structure in regional seismic velocity models. By refining the understanding of the WV’s impact on ground motion, this research contributes to more accurate seismic hazard assessments in the Pacific Northwest, showing the possible regional amplification.
Description
53 page thesis, 26 page document with supplementary data, and 1 video.
Keywords
3D physics-based Simulations, Ground Motion, Seismic Hazard, Seismology