CyberShake Study 24.8

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CyberShake Study 24.1 is an upcoming study in Northern California which includes deterministic low-frequency (0-1 Hz) and stochastic high-frequency (1-50 Hz) simulations. We will use the Graves & Pitarka (2022) rupture generator and the high frequency modules from the SCEC Broadband Platform v22.4.

Status

This study is in the planning phase. We hope to begin this study in January 2024.

Data Products

Science Goals

The science goals for this study are:

  • To perform an updated broadband study for the greater Bay Area.
  • To use an updated rupture generator and improved velocity model from Study 18.8.
  • To use the same parameters as in Study 22.12 when possible to make comparisons between the studies simple.

Technical Goals

The technical goals for this study are:

  • Use Frontier for the SGTs and Frontera for the post-processing and high-frequency calculations.
  • Use a modified approach for the production database, to improve performance.

Sites

Ruptures to Include

Historically, we have determined which ruptures to include in a CyberShake run by calculating the distance between the site and the closest part of the rupture surface. If that distance is less than 200 km, we then include all ruptures which take place on that surface, including ruptures which may extend much farther away from the site than 200 km.

For Northern California sites, this means that sites around San Jose and south include southern San Andreas events (events which rupture the northernmost segment of the southern San Andreas) within 200 km. Since there are some UCERF2 ruptures which extend from the Parkfield segment all the way down to Bombay Beach, the simulation volumes for some of these Northern California sites cover most of the state. This was the case for Study 18.8 (sample volumes can be seen on this page). This required tiling together 3 3D models and a background 1D model.

To simplify the velocity model and reduce the volumes, we are investigating omitting southern San Andreas events from this study.

Below are source contribution curves for 3 sites: s3430 (southwest corner of the study region), s3446 (southeast corner of the study region), and SJO (San Jose). In general, the sSAF events are about the 3rd largest contributor at long periods and medium-to-long return periods.

Site 2 sec 3 sec 5 sec 10 sec
s3430
S3430 run6408 2sec contributions.png
S3430 run6408 3sec contributions.png
S3430 run6408 5sec contributions.png
S3430 run6408 10sec contributions.png
s3446
S3446 run6452 2sec contributions.png
S3446 run6452 3sec contributions.png
S3446 run6452 5sec contributions.png
S3446 run6452 10sec contributions.png
SJO
SJO run6987 2sec contributions.png
SJO run6987 3sec contributions.png
SJO run6987 5sec contributions.png
SJO run6987 10sec contributions.png

We also looked at the source contributions for these 3 sites from ASK 2014. In general, the sSAF events play a reduced role compared to the CyberShake results.

Site 2 sec 3 sec 5 sec 10 sec
s3430
S3430 ASK2014 2sec contributions.png
S3430 ASK2014 3sec contributions.png
S3430 ASK2014 5sec contributions.png
S3430 ASK2014 10sec contributions.png
s3446
S3446 ASK2014 2sec contributions.png
S3446 ASK2014 3sec contributions.png
S3446 ASK2014 5sec contributions.png
S3446 ASK2014 10sec contributions.png
SJO
SJO ASK2014 2sec contributions.png
SJO ASK2014 3sec contributions.png
SJO ASK2014 5sec contributions.png
SJO ASK2014 10sec contributions.png

Velocity Model

Rupture Generator

High-frequency codes

Updates and Enhancements

Output Data Products

Computational and Data Estimates

Lessons Learned

Stress Test

Events During Study

Performance Metrics

Production Checklist

Presentations, Posters, and Papers

References