Plate Boundary Observatory

The Plate Boundary Observatory or (PBO) is one of three components of the Earthscope project, along with USArray and SAFOD (the San Andreas Fault Observatory at Depth).^[1] The PBO is exploring the structure and evolution of the North American continent and the processes related to earthquakes and volcanoes by installing an array of high precision Global Positioning System GPS monuments, borehole strainmeters, and tiltmeters throughout the western United States.^[2]^[3]^[4]
UNAVCO,^[5] a membership-governed consortium funded by the National Science Foundation (NSF) and NASA, installs the PBO. The network includes 1100 permanent, continuously operating Global Positioning System (GPS) stations many of which provide data at high-rate and in real-time, 78 borehole seismometers, 74 borehole strainmeters, 26 shallow borehole tiltmeters, and six long baseline laser strainmeters. These instruments are complemented by InSAR (interferometric synthetic aperture radar) and LiDAR (light detection and ranging) imagery and geochronology acquired as part of the GeoEarthScope initiative. PBO also includes comprehensive data products, data management and education and outreach efforts.

The GPS stations are categorized into five clusters. The transform cluster is in the vicinity of the San Andreas transform fault, which cuts through California; the subduction cluster is in the Cascadia subduction zone, which includes northern California, Oregon, Washington, and southern British Columbia, and is a result of the Juan de Fuca plate subducting under the North American plate; the extension cluster is in the Basin and Range region; the volcanic cluster is in volcanic regions such as the Yellowstone caldera, the Long Valley caldera, and the Cascade volcanoes; the backbone cluster is at 100–200 km across the United States to provide complete spatial coverage.

An EarthScope GPS sensor, a component of the Plate Boundary Observatory (PBO) system.

The GPS instrumentation is high-precision and continuously operating. High-precision means the units can detect sub-cm motion, and continuously operating means a 15 second sampling rate and one data file for every 24 hours. A completed PBO GPS station occupies about a three by three meter plot of land.

Some scientific questions that are being addressed by the EarthScope project and the PBO include:

How does accumulated strain lead to earthquakes?
Are there recognizable precursors to earthquakes?
How does the evolution of the continent influence the motions that are happening today?
What happens to geologic structures at depth?
What influences the location of features such as faults and mountain ranges?
Is it inherited from earlier tectonic events or related to deeper processes in the mantle?
How is magma generated? How does it travel from the mantle to reach the surface?
What are the precursors to a volcanic eruption?^[6]

References

^ EarthScope: An Earth Science Program
^ UNAVCO: Plate Boundary Observatory (PBO)
^ Vernon, Reyes, Eakins. "Array Network Facility". Retrieved 15 October 2014.{{cite web}}: CS1 maint: multiple names: authors list (link)
^ "Incorporated Research Institutions for Seismology". Retrieved 15 October 2014.
^ UNAVCO Home Page
^ National Research Council, Review of EarthScope Integrated Science (Washington D.C., National Academy Press, 2001).

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[1] EarthScope: An Earth Science Program

[2] UNAVCO: Plate Boundary Observatory (PBO)

[3] Vernon, Reyes, Eakins. "Array Network Facility". Retrieved 15 October 2014.{{cite web}}: CS1 maint: multiple names: authors list (link)

[4] "Incorporated Research Institutions for Seismology". Retrieved 15 October 2014.

[5] UNAVCO Home Page

[6] National Research Council, Review of EarthScope Integrated Science (Washington D.C., National Academy Press, 2001).

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