Your search keyword '"Field, Edward H."' showing total 3 results

1. Simplifying complex fault data for systems-level analysis: Earthquake geology inputs for U.S. NSHM 2023.

Author

Hatem, Alexandra E., Collett, Camille M., Briggs, Richard W., Gold, Ryan D., Angster, Stephen J., Field, Edward H., Powers, Peter M., Earthquake Geology Working Group, Anderson, Megan, Ben-Horin, Jeri Young, Dawson, Timothy, DeLong, Stephen, DuRoss, Christopher, Jobe, Jessica Thompson, Kleber, Emily, Knudsen, Keith L., Koehler, Richard, Koning, Daniel, Lifton, Zachery, and Madin, Ian

Subjects

GEOLOGY databases, EARTHQUAKE prediction, DATA analysis, GEOLOGY, EARTHQUAKES

Abstract

As part of the U.S. National Seismic Hazard Model (NSHM) update planned for 2023, two databases were prepared to more completely represent Quaternary-active faulting across the western United States: the NSHM23 fault sections database (FSD) and earthquake geology database (EQGeoDB). In prior iterations of NSHM, fault sections were included only if a field-measurement-derived slip rate was estimated along a given fault. By expanding this inclusion criteria, we were able to assess a larger set of faults for use in NSHM23. The USGS Quaternary Fault and Fold Database served as a guide for assessing possible additions to the NSHM23 FSD. Reevaluating available data from published sources yielded an increase of fault sections from ~650 faults in NSHM18 to ~1,000 faults proposed for use in NSHM23. EQGeoDB, a companion dataset linked to NSHM23 FSD, contains geologic slip rate estimates for fault sections included in FSD. Together, these databases serve as common input data used in deformation modeling, earthquake rupture forecasting, and additional downstream uses in NSHM development. Measurement(s) N/A Technology Type(s) N/A [ABSTRACT FROM AUTHOR]

Published

2022

2. First Results of the Regional Earthquake Likelihood Models Experiment.

Author

Schorlemmer, Danijel, Zechar, J. Douglas, Werner, Maximilian J., Field, Edward H., Jackson, David D., and Jordan, Thomas H.

Subjects

EARTHQUAKES, NATURAL disaster research, EARTH movements, EARTHQUAKE prediction, GEOPHYSICAL prediction

Abstract

The ability to successfully predict the future behavior of a system is a strong indication that the system is well understood. Certainly many details of the earthquake system remain obscure, but several hypotheses related to earthquake occurrence and seismic hazard have been proffered, and predicting earthquake behavior is a worthy goal and demanded by society. Along these lines, one of the primary objectives of the Regional Earthquake Likelihood Models (RELM) working group was to formalize earthquake occurrence hypotheses in the form of prospective earthquake rate forecasts in California. RELM members, working in small research groups, developed more than a dozen 5-year forecasts; they also outlined a performance evaluation method and provided a conceptual description of a Testing Center in which to perform predictability experiments. Subsequently, researchers working within the Collaboratory for the Study of Earthquake Predictability (CSEP) have begun implementing Testing Centers in different locations worldwide, and the RELM predictability experiment—a truly prospective earthquake prediction effort—is underway within the U.S. branch of CSEP. The experiment, designed to compare time-invariant 5-year earthquake rate forecasts, is now approximately halfway to its completion. In this paper, we describe the models under evaluation and present, for the first time, preliminary results of this unique experiment. While these results are preliminary—the forecasts were meant for an application of 5 years—we find interesting results: most of the models are consistent with the observation and one model forecasts the distribution of earthquakes best. We discuss the observed sample of target earthquakes in the context of historical seismicity within the testing region, highlight potential pitfalls of the current tests, and suggest plans for future revisions to experiments such as this one. [ABSTRACT FROM AUTHOR]

Published

2010

3. Nonlinear ground-motion amplification by sediments during the 1994 Northridge earthquake.

Author

Field, Edward H. and Johnson, Paul A.

Subjects

*EARTHQUAKES, *SEDIMENTS

Abstract

Presents research which reported that ground-motion amplification due to sediments for the main shock of the 1994 Northridge earthquake was up to a factor of two less than the amplification observed for its aftershocks. Sediments amplifying earthquake ground motion relative to bedrock; Linear elasticity and Hooke's law; Implications of research; Questioning the use of measurements of weak ground motion to predict strong ground motion.

Published

1997