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Community Modeling Environment (CME)

This is a collaborative wiki site for SCEC's Community Modeling Environment (CME). The CME is a collaborative, interdisciplinary research group that applies advanced computer science technology to the problem of seismic hazard analysis. This SCEC community wiki is configured to support our distributed research by providing a collection point for information about SCEC scientific computing research projects.

Recently Updated CME Project Entries

List of SCEC Scientific Software

Collaborative Information Entries

List of All SCECpedia Pages

The following link will take you to an alphabetically sorted list of all SCECpedia pages.

The following link will take you to a list of the most frequently visited SCECpedia pages .

Fig 1: SCEC/CME computational pathways provide a scientific framework for improving seismic ground motion forecasts. The SCEC/CME Project began as an NSF information technology research (ITR) project in 2001. (Image Credit: Thomas H. Jordan)

Recent Earthquake Information

An important goal of SCEC earthquake research is to reduce the hazard from future earthquakes by developing physics-based predictive models of earthquake processes.

SCEC and CME-related Web Sites

Fig 0: USGS Hazard Map
Fig 1: SCEC Full 3D Inversion research is using ALCF Mira.
Fig 2: Petascale wave propagation simulation was run in April 2013 on NCCS Titan.
Fig 3: M8 Dynamic Rupture simulation was run in March 2010 on NICS Kraken.
Fig 4: M8 Wave propagation simulation was run in April 2010 on NCCS Jaguar.
Fig 5: Two minutes after origin time for the SCEC M8 simulation showing velocity magnitude through local elevation. (Image Credit: Amit Chourasia)

CME Research Support

Southern California Earthquake Center (SCEC) and SCEC/CME research is funded by National Science Foundation (NSF) Cooperative Agreements EAR-0106924 and USGS Cooperative Agreement 02HQAG0008, and NSF awards EAR- 074493, EAR-0949443, OCI-0832698, and OCI-0832698. This research is supported by an allocation of advanced computing resources provided by the National Science Foundation (NSF). Computations are performed on Kraken (a Cray XT5) at the National Institute for Computational Sciences. Computations and data management are performed at San Diego Supercomputer Center, where the iRODS Data System is used. The Texas Advanced Computing Center (TACC) at The University of Texas at Austin, the National Center for Supercomputer Applications (NCSA) and the Pittsburgh Supercomputer Center (PSC) provide HPC resources. Computations are supported by the University of Southern California Center for High-Performance Computing and Communications (HPCC). Our research uses HPC resources provided by the U.S. Department of Energy (DOE) through an Innovative and Novel Computational Impact on Theory and Experiment (INCITE) program allocation award. Computations were performed on Jaguar, which is part of the National Center for Computational Science (NCCS) at the Oak Ridge National Laboratory which is supported by under DOE Contract No. DE-AC05-00OR22725. This research uses resources of the Argonne Leadership Computing Facility at Argonne National Laboratory, which is supported by the Office of Science of the U.S. Department of Energy under contract DE-AC02- 06CH11357. The Ohio State University one-sided MPI Communication research was supported through NSF HECURA-1 (CCF- 0833169/139/155). This research received technical and user support through the Advanced Support for TeraGrid Applications (ASTA) program.

See Also

Additional information about SCEC earthquake system science research is available on related SCEC web sites including:

License

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