| NSF Org: |
OCE Division Of Ocean Sciences |
| Recipient: |
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| Initial Amendment Date: | June 13, 2018 |
| Latest Amendment Date: | December 10, 2020 |
| Award Number: | 1825861 |
| Award Instrument: | Standard Grant |
| Program Manager: |
Deborah K. Smith
OCE Division Of Ocean Sciences GEO Directorate for Geosciences |
| Start Date: | July 1, 2018 |
| End Date: | June 30, 2021 (Estimated) |
| Total Intended Award Amount: | $168,174.00 |
| Total Awarded Amount to Date: | $199,020.00 |
| Funds Obligated to Date: |
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| History of Investigator: |
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| Recipient Sponsored Research Office: |
266 WOODS HOLE RD WOODS HOLE MA US 02543-1535 (508)289-3542 |
| Sponsor Congressional District: |
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| Primary Place of Performance: |
266 Woods Hole Road Woos Hole MA US 02543-1535 |
| Primary Place of
Performance Congressional District: |
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| Unique Entity Identifier (UEI): |
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| Parent UEI: |
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| NSF Program(s): | Marine Geology and Geophysics |
| Primary Program Source: |
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| Program Reference Code(s): | |
| Program Element Code(s): |
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| Award Agency Code: | 4900 |
| Fund Agency Code: | 4900 |
| Assistance Listing Number(s): | 47.050 |
ABSTRACT
Large earthquakes and tsunamis can occur due to the motion of Earth's tectonic plates at plate boundaries where oceanic crust is subducted under overlying crust in places such as Cascadia, which is offshore of the northwestern US near Vancouver Island, or Japan. Faults causing these earthquakes sometimes rupture from deep in Earth's crust all the way up to the surface of the seafloor. When that happens, displacement of the seafloor occurs; and, depending on the size of the up-thrust, this can generate a megatsunami. One such example would be the magnitude 9 earthquake that struck Japan in 2011 and generated a major tsunami that devastated communities along Japan's northeastern shore. Not all subduction ruptures, however, create such large tsunamis because, in some, displacements are confined along parts of faults that are well below the ocean floor. This can be seen in the 2014 magnitude 8.3 Chile Iquique earthquake which did not cause any major tsunami because most displacement in the Earth occurred at depths around 10 km. This research focuses on collecting and improving seismic data in the Cascadia region that is streaming from a unique subseafloor borehole geophysical observatory. These data are being used to study fault mechanics in the Cascadia area and provide tsunami hazard forecasts. Cascadia is an area of interest because it is close to the US and is a place where active subduction is occurring and for which there are no known large subduction-related earthquakes. It is important to understand if this "locking" of the fault is real, thus raising concern that accumulating stress is building up and result in a major earthquake or if the stress is being released through a series of slow and low, slip events. To help understand the fault dynamics in the Cascadia area, in 2016 a unique borehole geophysical installation was established in the seafloor off Vancouver Island on the Ocean Networks Canada cabled observatory. This research calibrates and validates data streaming from the borehole installation to test its reliability and provide real time-seismic and geodetic data from the shallowest part of the Cascadia subduction zone. This new system is designed to be especially sensitive to ruptures and properties in the shallow parts of the Cascadia fault zone. Broader impacts of the work include increasing infrastructure for science in terms of developing the unique capabilities of this new installation and providing important hazards-related data for earthquakes and potential mega tsunamis generated by continued subduction of the ocean plate under the northwest US and Canada. It also represents an important collaboration between the US and Canadian scientists running the Ocean Networks Canada cabled undersea observatory and the leveraging of infrastructure from the NSF International Ocean Discovery Program.
In 2016, an international team of US and Canadian scientists and engineers installed a borehole geophysical observatory in the seafloor near the up-dip end of the Cascadia subduction zone offshore of Vancouver Island on the Canadian cabled observatory. Since 2017, this system has been returning high quality, real-time, seismic and borehole tilt data. Sensors are positioned about 300 m below the seafloor and about 4 km above the Cascadia plate boundary fault. Initial analysis of the data indicates the borehole system should be able to detect low magnitude, slow slip, earthquake events as small as magnitude 4. However, many small signals and excursions in the data still remain to be investigated to determine their sources and establish the stability of the instruments and the reliability of their data. This research continues the improvement of streaming data and determining its reliability. It involves optimizing the borehole instrumentation, with a focus on improving the de-tiding algorithm, cataloging potential transients at different time scales, and investigating instrument performance and stability. These activities ensure the best data quality for all users, ranging from scientists to managers of real-time warning systems who study earthquakes and tsunamis. Data from the borehole observatory can also be used to detect and track marine mammals and provide information on gas hydrate stability. The work will also ensure the dataset collected is archived if there are outages in telemetry.
This award reflects NSF's statutory mission and has been deemed worthy of support through evaluation using the Foundation's intellectual merit and broader impacts review criteria.
PUBLICATIONS PRODUCED AS A RESULT OF THIS RESEARCH
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PROJECT OUTCOMES REPORT
Disclaimer
This Project Outcomes Report for the General Public is displayed verbatim as submitted by the Principal Investigator (PI) for this award. Any opinions, findings, and conclusions or recommendations expressed in this Report are those of the PI and do not necessarily reflect the views of the National Science Foundation; NSF has not approved or endorsed its content.
The primary science objective of this award (and a related earlier award) is to understand the first-order variation in megathrust rupture. Why do some great subduction zone earthquakes rupture all the way to the trench while others only rupture the deeper fault zone? This has become a central question for both basic fault mechanics and for tsunami hazard forecasts. A variety of factors likely contribute to event variability including fault-zone mineralogy, fluid pressures, dynamic stress fields, and the influence of splay faults. We do not yet have the ability to geologically characterize a particular subduction zone and forecast whether or not its next large rupture is likely to involve considerable shallow slip, and hence a truly devastating tsunami such as in Tohoku and 2004 Sumatra.
We used data from a borehole seismic, geodetic, and geothermal observatory installed at the up-dip end of the Cascadia fault offshore Vancouver Island to show that the megathrust there does not appear to slip in triggered tremor or slow-slip events when subjected to moderate dynamic stress transients. (The borehole observatory was installed using a related NSF award.) Borehole tilt and seismic data from teleseismic M7.6?8.1 earthquakes demonstrate a lack of triggered slow slip above the Mw 4.0 level and an absence of triggered tremor despite shear-stress transients of 1?10 kPa that were sufficient to trigger tremor on the downdip end of the interface. Our observations are most consistent with a model in which the Cascadia fault offshore Vancouver Island is locked all the way to the trench. Our initial observations indicate that the borehole system is capable of detecting slow slip events as small as magnitude 4.
The original goals of this project were two-fold: (1) to optimize the seismic/geodetic/thermal instrumentation that we had previously installed in IODP Hole U1364A offshore Vancouver Island at the up-dip end of the Cascadia subduction zone; and (2) to utilize the real-time data streaming from the observatory to determine if models where interseismic locking extends all the way to the trench in Cascadia are supported or rejected by the observations of the presence or lack of slow slip events, very low frequency earthquakes, and tremor.
Unfortunately, our equipment stopped communicating via the Ocean Networks Canada fiber-optic cable in June 2018, due to a bad memory unit in a network switch in a piece of our equipment sitting in the borehole reentry cone. Repairing this system required recovery of the entire borehole package via ROV. In a supplement to this award, we requested four days on-station of ship/ROV time to recover, repair, and redeploy the system. That cruise iook p place on the R/V Sikuliaq in September 2019 as the ship transited from Kodiak, AK to Newport, OR. The funds requested in the supplement were for presennel to go on the cruise and recover the system; this was not part of the original proposal.
Once we had the equipment back at WHOI, we replaced the failed network switch, and sent the tiltmeter sensors back to the manufacturer for refurbishment. We also re-tested the 270 m armored cable that links the downhole sensor package with the control package that sits in the re-entry cone. We stretched the cable at a local airfield and verifed electrical continuity. We then re-installed the complete system in the test borehole outside the WHOI OBS lab.
Last Modified: 03/30/2022
Modified by: John A Collins
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