Optimization of a Simulation Code Coupling Extended Source (k−2) and Empirical Green’s Functions: Application to the Case of the Middle Durance Fault

Optimization of a Simulation Code Coupling Extended Source (k−2) and Empirical Green’s Functions: Application to the Case of the Middle Durance Fault

We developed a ground-motion simulation code base on extended rupture modeling combined with the use of empirical Green’s functions (EGFs), adapted for low-to-moderate seismicity regions (with a limited set of EGFs), and extended its range of applicability to the lowest source-to-site distances. Thi...

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Bibliographic Details
Published in:Pure and applied geophysics Vol. 177; no. 5; pp. 2255 - 2279
Main Authors: Dujardin, Alain, Hollender, Fabrice, Causse, Mathieu, Berge-Thierry, Catherine, Delouis, Bertrand, Foundotos, Laetitia, Ameri, Gabriele, Shible, Hussein
Format: Journal Article
Language:English
Published: Cham Springer International Publishing 01-05-2020
Springer Nature B.V
Springer Verlag
Subjects:
Anelasticity
Attenuation
Computer simulation
Earth and Environmental Science
Earth Sciences
Fault lines
Geophysics
Geophysics/Geodesy
Ground motion
Motion simulation
Nuclear research
Optimization
Radiation
Recording
Rocks
Rupture
Rupturing
Sciences of the Universe
Sediment
Seismicity
Simulation
Time lag
Variability
K2 extended source simulations
GMPEs
Empirical Green’s functions
rock site definition
ground motion simulation variability
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Summary:We developed a ground-motion simulation code base on extended rupture modeling combined with the use of empirical Green’s functions (EGFs), adapted for low-to-moderate seismicity regions (with a limited set of EGFs), and extended its range of applicability to the lowest source-to-site distances. This code is based on a kinematic source description of an extended fault and is designed to allow complex fault geometries and to generate a ground motion variability in agreement with that of the recorded databases. The code is developed to work with a sparse set of EGFs. Each available EGF is therefore used in several positions on the rupture area. To be used in positions different of their original position, we applied to the EGFs some adjustments. In addition to the classical adjustments (i.e. time delay correction, geometrical spreading correction and anelastic attenuation correction), we propose here a radiation pattern adjustment. The effectiveness of it is tested in a numerical application. We showed noticeable improvements at the lowest distances, and some limitations when approaching the nodal planes of the subevents the recording of which were used as EGFs. We took advantage of the development of this code, its ability to work with a sparse set of EGFs, its ability to take into account complex fault geometries and its ability to master the general variability, to perform a ground-motion simulation scenario on the Middle Durance Fault (MDF). We perform simulations for a hard rock site (V S30  = 1800 m/s) and a sediment site (V S30  = 440 m/s) of the CEA Nuclear Research Site of Cadarache (France), and compared the computed ground motion with several ground motion prediction equations (GMPEs). The GMPEs slightly underestimate the sediment site but strongly overestimate the ground motion amplitude on the hard rock site, even when using a specific correction factor which adapts GMPEs predictions from rock site to hard rock site. This general ascertainment confirms the need to continue efforts towards the establishment of consistent GMPEs applicable to hard-rock conditions.
ISSN:0033-4553
1420-9136
DOI:10.1007/s00024-019-02309-x