Group A, Poster #169, Ground Motions (GM)
Earthquake-source parameters: Are they what you think they are?
Poster Image:
Poster Presentation
2024 SCEC Annual Meeting, Poster #169, SCEC Contribution #13828 VIEW PDF
nates, however how “depth” is defined is not standardized. Some catalogs report Zhyp relative to the WGS84 geoid (i.e., mean sea level), whereas others report Zhyp relative to the ground surface or other datums. As long as the reference datum is known for all catalogs, adjustments can be made to obtain a compatible dataset. More often than not, documentation for this type of information is not presented in catalogs, requiring targeted efforts to produce consistent source metadata.
Finite fault models (FFMs) are another critical component of source characterization that present a different set of challenges. It is becoming more common for many teams of researchers to publish FFMs following significant earthquakes, such as the 2023 Kahramanmaraş, Türkiye earthquakes. These FMMs are used to derive source-to-site distances that are used to develop ground motion models. Ideally, FFMs are developed using a variety of data types (e.g., aftershocks, GPS, InSAR, teleseismic, etc.) including at a minimum local strong ground motions and considering the presence or lack of surface rupture. It is most beneficial when FFM slip distributions are provided in a digital format to facilitate further analysis and processing (e.g., calculation of site distance and other metrics, trimming to remove areas that do not contribute to significant ground motions, comparison among models for same event, etc.). FFMs are not used when they do not satisfy these criteria or do not provide sufficient documentation about their development.
Our recommendation is to increase communication between data-providers and data-users, which is facilitated by engineers participating in science-focused meetings like SCEC-2024 and corollary seismologist engagement in engineering meetings.
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Finite fault models (FFMs) are another critical component of source characterization that present a different set of challenges. It is becoming more common for many teams of researchers to publish FFMs following significant earthquakes, such as the 2023 Kahramanmaraş, Türkiye earthquakes. These FMMs are used to derive source-to-site distances that are used to develop ground motion models. Ideally, FFMs are developed using a variety of data types (e.g., aftershocks, GPS, InSAR, teleseismic, etc.) including at a minimum local strong ground motions and considering the presence or lack of surface rupture. It is most beneficial when FFM slip distributions are provided in a digital format to facilitate further analysis and processing (e.g., calculation of site distance and other metrics, trimming to remove areas that do not contribute to significant ground motions, comparison among models for same event, etc.). FFMs are not used when they do not satisfy these criteria or do not provide sufficient documentation about their development.
Our recommendation is to increase communication between data-providers and data-users, which is facilitated by engineers participating in science-focused meetings like SCEC-2024 and corollary seismologist engagement in engineering meetings.
SHOW MORE
Citation: Buckreis, T. E., Chiou, B. S., Darragh, R. B., Graves, R. W., & Stewart, J. P. (2024, 09). Earthquake-source parameters: Are they what you think they are?. Poster Presentation at 2024 SCEC Annual Meeting.
Keywords: earthquake, hypocentral depth, finite-fault models, parameters, database
Relevant SCEC Themes:
Improving Observations and Closing Data Gaps
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