Calibrated Absolute Seafloor Pressure Measurements for Geodesy in Cascadia

The boundary between the overriding and subducting plates is locked along some portions of the Cascadia subduction zone. The extent and location of locking affects the potential size and frequency of great earthquakes in the region. Because much of the boundary is offshore, measurements on land are...

Full description

Saved in:
Bibliographic Details
Published in:Journal of geophysical research. Solid earth 2023-06, Vol.128 (6), p.n/a
Main Authors: Cook, Matthew J., Fredrickson, Erik K., Roland, Emily C., Sasagawa, Glenn S., Schmidt, David A., Wilcock, William S. D., Zumberge, Mark A.
Format: Article
Language:English
Subjects:
absolute pressure
Accretion
Accuracy
Benchmarks
calibrated pressure
Calibration
Cascadia subduction zone
Crustal deformation
Deformation
Drift
Earthquakes
Equivalence
Error correction
Gauges
Geodesy
Geological processes
Geophysics
Height
Hydrostatic pressure
Locking
marine geophysics
Ocean floor
Offshore
piston gauge calibrator
Plate tectonics
Plates (tectonics)
Pressure gages
Pressure gauges
Pressure measurement
Pressure recorders
seafloor geodesy
Seismic activity
Sensors
Subduction
Subduction (geology)
Subduction zones
Surveys
Uplift
Water depth
Water pressure
Citations: Items that this one cites
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:The boundary between the overriding and subducting plates is locked along some portions of the Cascadia subduction zone. The extent and location of locking affects the potential size and frequency of great earthquakes in the region. Because much of the boundary is offshore, measurements on land are incapable of completely defining a locked zone in the up‐dip region. Deformation models indicate that a record of seafloor height changes on the accretionary prism can reveal the extent of locking. To detect such changes, we have initiated a series of calibrated pressure measurements using an absolute self‐calibrating pressure recorder. A piston‐gauge calibrator under careful metrological considerations produces an absolutely known reference pressure to correct seafloor pressure observations to an absolute value. We report an accuracy of about 25 ppm of the water depth, or 0.02 kPa (0.2 cm equivalent) at 100 m to 0.8 kPa (8 cm equivalent) at 3,000 m. These campaign survey‐style absolute pressure measurements on seven offshore benchmarks in a line extending 100 km westward from Newport, Oregon from 2014 to 2017 establish a long‐term, sensor‐independent time series that can, over decades, reveal the extent of vertical deformation and thus the extent of plate locking and place initial limits on rates of subsidence or uplift. Continued surveys spanning years could serve as calibration values for co‐located or nearby continuous pressure records and provide useful information on possible crustal deformation rates, while epoch measurements spanning decades would provide further limits and additional insights on deformation. Plain Language Summary The Cascadia subduction zone has produced large earthquakes and tsunamis whose potential size and interval is affected by the amount and distribution of locking between the tectonic plates. A large portion of the subduction zone is offshore, where typical land‐ and satellite‐based methods are ineffective at measuring crustal changes. Seafloor water pressure observations can be used to measure height changes, but pressure gauges inherently drift at rates typically greater than the expected vertical seafloor deformation rates. The absolute self‐calibrating pressure recorder (ASCPR) measures the true, absolute, sensor‐independent seafloor pressure by addressing and correcting sources of error caused by the internal piston gauge calibrator and recording pressure gauges. The accuracy of our measurements is about 25 ppm of the water
ISSN:2169-9313
2169-9356
DOI:10.1029/2023JB026413