Probabilistic Forecasting of Earthquakes, Tsunamis, and Earthquake Effects in the Coastal Zone
The nation's coastlines are vulnerable to the interrelated hazards posed by earthquakes, landslides, and tsunamis. In the marine environment these events often occur in concert, and distant triggers can cause severe local effects, making the issue global in scope. As the population continues to migrate toward the coastlines, the social impacts of these hazards are expected to grow.
Products are aimed for use in regional multi-hazard assessments, and might range from complete assessments to analysis tools, interpreted data, or models. We are interacting with groups tasked with making formal hazard assessments and have provided products needed by them in a timely manner (e.g., Southern California Earthquake Center (SCEC), Working Group on California Earthquake Probabilities (WGCEP)). These collaborations will continue to be a major guiding influence, and we plan to maintain research flexibility needed for proper response as necessary. As such, the task is defined thematically. The larger community will help to establish guidelines on regions in which we will we work.
Research Web Sites
Tsunami and Earthquake Research
This site provides general information about how earthquakes generate tsunamis, as well as descriptions and animations of historical tsunamis, virtual reality models showing how tsunamis change as they approach and bounce off coastlines, and summaries of past fieldwork in areas struck by major tsunamis.
Earthquake Hazards Program
We work closely with scientists in the USGS Earthquake Hazards Program, with the goal of providing relevant scientific information to reduce deaths, injuries, and property damage from earthquakes.
Working Group on California Earthquake Probabilities (WGCEP)
We collaborate with groups that make formal hazard assessments, such as the Working Group on California Earthquake Probabilities (WGCEP), providing and evaluating the latest scientific information. This site presents the most recent collaborative earthquake forecasts for all of California.
Global Geoengineering Research
The Coastal and Marine Geology geoengineering group investigates the causes of ground deformation and ground failures—such as landslides and liquefaction—that result from earthquakes, storms, and wave action.
Below are other science projects associated with this project.
Below are publications associated with this project.
A global search for stress shadows
Global ubiquity of dynamic earthquake triggering
Persistent earthquake clusters and gaps from slip on irregular faults
Triggering of tsunamigenic aftershocks from large strike‐slip earthquakes: Analysis of the November 2000 New Ireland earthquake sequence
[1] The November 2000 New Ireland earthquake sequence started with a Mw = 8.0 left‐lateral main shock on 16 November and was followed by a series of aftershocks with primarily thrust mechanisms. The earthquake sequence was associated with a locally damaging tsunami on the islands of New Ireland and nearby New Britain, Bougainville, and Buka. Results from numerical tsunami‐propagation models of the
Structure and mechanics of the San Andreas–San Gregorio fault junction, San Francisco, California
[1] The right‐lateral San Gregorio and San Andreas faults meet west of the Golden Gate near San Francisco. Coincident seismic reflection and refraction profiling across the San Gregorio and San Andreas faults south of their junction shows the crust between them to have formed shallow extensional basins that are dissected by parallel strike‐slip faults. We employ a regional finite element model to
Large-scale deformation related to the collision of the Aleutian Arc with Kamchatka
Application of continuum models to deformation of the Aleutian Island Arc
Continuum models were constructed to describe large‐scale deformation of the Aleutian Island Arc over the past 5 m.y. These models consider the island arc as a continuum in the horizontal plane with the velocity boundary condition at the Pacific edge stated as a fraction of Pacific plate convergence transferred to the arc. First, a simple model of uniformly distributed strain is formulated to illu
Below are news stories associated with this project.
Below are FAQ associated with this project.
The nation's coastlines are vulnerable to the interrelated hazards posed by earthquakes, landslides, and tsunamis. In the marine environment these events often occur in concert, and distant triggers can cause severe local effects, making the issue global in scope. As the population continues to migrate toward the coastlines, the social impacts of these hazards are expected to grow.
Products are aimed for use in regional multi-hazard assessments, and might range from complete assessments to analysis tools, interpreted data, or models. We are interacting with groups tasked with making formal hazard assessments and have provided products needed by them in a timely manner (e.g., Southern California Earthquake Center (SCEC), Working Group on California Earthquake Probabilities (WGCEP)). These collaborations will continue to be a major guiding influence, and we plan to maintain research flexibility needed for proper response as necessary. As such, the task is defined thematically. The larger community will help to establish guidelines on regions in which we will we work.
Research Web Sites
Tsunami and Earthquake Research
This site provides general information about how earthquakes generate tsunamis, as well as descriptions and animations of historical tsunamis, virtual reality models showing how tsunamis change as they approach and bounce off coastlines, and summaries of past fieldwork in areas struck by major tsunamis.
Earthquake Hazards Program
We work closely with scientists in the USGS Earthquake Hazards Program, with the goal of providing relevant scientific information to reduce deaths, injuries, and property damage from earthquakes.
Working Group on California Earthquake Probabilities (WGCEP)
We collaborate with groups that make formal hazard assessments, such as the Working Group on California Earthquake Probabilities (WGCEP), providing and evaluating the latest scientific information. This site presents the most recent collaborative earthquake forecasts for all of California.
Global Geoengineering Research
The Coastal and Marine Geology geoengineering group investigates the causes of ground deformation and ground failures—such as landslides and liquefaction—that result from earthquakes, storms, and wave action.
Below are other science projects associated with this project.
Below are publications associated with this project.
A global search for stress shadows
Global ubiquity of dynamic earthquake triggering
Persistent earthquake clusters and gaps from slip on irregular faults
Triggering of tsunamigenic aftershocks from large strike‐slip earthquakes: Analysis of the November 2000 New Ireland earthquake sequence
[1] The November 2000 New Ireland earthquake sequence started with a Mw = 8.0 left‐lateral main shock on 16 November and was followed by a series of aftershocks with primarily thrust mechanisms. The earthquake sequence was associated with a locally damaging tsunami on the islands of New Ireland and nearby New Britain, Bougainville, and Buka. Results from numerical tsunami‐propagation models of the
Structure and mechanics of the San Andreas–San Gregorio fault junction, San Francisco, California
[1] The right‐lateral San Gregorio and San Andreas faults meet west of the Golden Gate near San Francisco. Coincident seismic reflection and refraction profiling across the San Gregorio and San Andreas faults south of their junction shows the crust between them to have formed shallow extensional basins that are dissected by parallel strike‐slip faults. We employ a regional finite element model to
Large-scale deformation related to the collision of the Aleutian Arc with Kamchatka
Application of continuum models to deformation of the Aleutian Island Arc
Continuum models were constructed to describe large‐scale deformation of the Aleutian Island Arc over the past 5 m.y. These models consider the island arc as a continuum in the horizontal plane with the velocity boundary condition at the Pacific edge stated as a fraction of Pacific plate convergence transferred to the arc. First, a simple model of uniformly distributed strain is formulated to illu
Below are news stories associated with this project.
Below are FAQ associated with this project.