Abstract
We implement a Distributed Seismic Moment (DSM) fault model, a
physics-based representation of an earthquake source based on a
skewed-Gaussian slip distribution over an elliptical rupture patch, for
the purpose of forward modeling of seismic-wave propagation in 3-D
heterogeneous medium. The elliptical rupture patch is described by 13
parameters: location (3), dimensions of the patch (2), patch orientation
(1), focal mechanism (3), nucleation point (2), peak slip (1), rupture
velocity (1). A node based second order finite difference approach is
used to solve the seismic-wave equations in displacement formulation
(WPP, Nilsson et al., 2007). Results of our DSM fault model are compared
with three commonly used fault models: Point Source Model (PSM),
Haskell's fault Model (HM), and HM with Radial (HMR) rupture
propagation. Spectral features of the waveforms and radiation patterns
from these four models are investigated. The DSM fault model best
incorporates the simplicity and symmetry of the PSM with the directivity
effects of the HMR while satisfying the physical requirements, i.e.,
smooth transition from peak slip at the nucleation point to zero at the
rupture patch border. The implementation of the DSM in seismic-wave
propagation forward models comes at negligible computational cost.
Reference: Nilsson, S., Petersson, N. A., Sjogreen, B., and Kreiss,
H.-O. (2007). Stable Difference Approximations for the Elastic Wave
Equation in Second Order Formulation. SIAM Journal on Numerical
Analysis, 45(5), 1902-1936.
Original language | English |
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Title of host publication | EGU General Assembly 27/04 - 2/05/14 Vienna, Austria |
Pages | 6665 |
State | Published - 1 May 2014 |
Event | EGU General Assembly 2014 - Vienna, Austria Duration: 27 Apr 2014 → 2 May 2014 |
Conference
Conference | EGU General Assembly 2014 |
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Country/Territory | Austria |
City | Vienna |
Period | 27/04/14 → 2/05/14 |