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ShakeOut‐D: Ground motion estimates using an ensemble of large earthquakes on the southern San Andreas fault with spontaneous rupture propagation
Author(s) -
Olsen K. B.,
Day S. M.,
Dalguer L. A.,
Mayhew J.,
Cui Y.,
Zhu J.,
CruzAtienza V. M.,
Roten D.,
Maechling P.,
Jordan T. H.,
Okaya D.,
Chourasia A.
Publication year - 2009
Publication title -
geophysical research letters
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 2.007
H-Index - 273
eISSN - 1944-8007
pISSN - 0094-8276
DOI - 10.1029/2008gl036832
Subject(s) - san andreas fault , geology , seismology , kinematics , parameterized complexity , attenuation , ground motion , fault (geology) , strong ground motion , geodesy , physics , mathematics , classical mechanics , optics , combinatorics
We simulate ground motion in southern California from an ensemble of 7 spontaneous rupture models of large (M w 7.8) northwest‐propagating earthquakes on the southern San Andreas fault (ShakeOut‐D). Compared to long‐period spectral accelerations from the Next Generation Attenuation (NGA) empirical relations, ShakeOut‐D predicts similar average rock‐site values (i.e., within roughly their epistemic uncertainty), but significantly larger values in Los Angeles and Ventura basins due to wave‐guide focusing effects. The ShakeOut‐D ground motion predictions differ from those of a kinematically parameterized, geometrically similar, scenario rupture: (1) the kinematic rock‐site predictions depart significantly from the common distance‐attenuation trend of the NGA and ShakeOut‐D results and (2) ShakeOut‐D predictions of long‐period spectral acceleration within the basins of the greater Los Angeles area are lower by factors of 2–3 than the corresponding kinematic predictions. We attribute these differences to a less coherent wavefield excited by the complex rupture paths of the ShakeOut‐D sources.