Effects of simulated magnitude 9 earthquake motions on structures in the Pacific Northwest

Nasser A. Marafi; M. Eberhard; J. Berman; Erin A. Wirth; Arthur D. Frankel; J. Vidale

Effects of simulated magnitude 9 earthquake motions on structures in the Pacific Northwest

By: Nasser A. Marafi, M. Eberhard, J. Berman, Erin A. Wirth, Arthur D. Frankel, and J. Vidale

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Abstract

The Cascadia Subduction Zone (CSZ) produces long-duration, large-magnitude earthquakes that could severely affect structures in the Pacific Northwest (PNW). The impact of synthetic M9.0 CSZ earthquakes on buildings in the Pacific Northwest is studied using eight reinforced concrete wall archetypes that range from 4 to 40 stories. These archetypes were subjected to an ensemble of simulated ground-motions from 30 M9 earthquakes for a location in Seattle that overlies a ~8km deep sedimentary basin and an equivalent location outside the basin. Long-period (1-7s) ground motions are strongly amplified in the CSZ synthetics within the Seattle Basin, leading to a 6-fold increase in deformation demand (inter-story drift) compared to an equivalent out of basin site. The variability in demand was also found to be much larger inside the basin than outside the basin.

Additional publication details
Publication type	Conference Paper
Publication Subtype	Conference Paper
Title	Effects of simulated magnitude 9 earthquake motions on structures in the Pacific Northwest
Year Published	2018
Language	English
Publisher	Earthquake Engineering Research Institute (EERI)
Contributing office(s)	Earthquake Science Center
Description	5 p.
Conference Title	11th U.S.National Conference on Earthquake Engineering
Conference Location	Los Angeles, CA
Conference Date	June 25-29, 2018