Calibrated absolute seafloor pressure measurements for geodesy in Cascadia

Cook, Matthew; Fredrickson, Erik K.; Roland, E. C.; Sasagawa, G. S.; Schmidt, D. A.; Wilcock, William S. D.; Zumberge, Mark A.

doi:10.22541/essoar.167525205.55700045/v1

Cited by 2 publications

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“…Data are available from the UC San Diego Library Digital Collections at https://doi.org/10.6075/J0F18ZXJ (Cook et al., 2023). The published data include raw data files, the necessary metadata to convert the raw data into physical units, and the final absolute sea pressure time series for each survey.…”

Section: Data Availability Statementmentioning

confidence: 99%

Calibrated Absolute Seafloor Pressure Measurements for Geodesy in Cascadia

et al. 2023

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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.

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Section: Data Availability Statementmentioning

confidence: 99%

Calibrated Absolute Seafloor Pressure Measurements for Geodesy in Cascadia

et al. 2023

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“…Earth's surface water forms a natural electromagnetic barrier for direct use of space‐based geodetic techniques to measure seafloor motion, resulting in a large portion of the solid Earth surface not being geodetically monitored. Community efforts in developing seafloor geodetic methods, including GNSS‐acoustic ranging (GNSS‐A) (e.g., Spiess, 1985; Spiess et al., 1998; Gagnon et al., 2005; Chadwell & Spiess, 2008; Chadwell & Sweeney, 2010; Chen et al., 2020; Watanabe et al., 2020), direct or indirect‐path acoustic ranging (e.g., Blum et al., 2010; McGuire & Collins, 2013; Petersen et al., 2019), ocean bottom pressure measurements (e.g., Sasagawa & Zumberge, 2013; Wilcock et al., 2021; Sasagawa et al., 2023; Cook et al., 2023), spar‐buoys (e.g., De Martino et al., 2014; Xie et al., 2019), borehole pressure measurements (e.g., Davis et al., 1992), and cabled strainmeters (Zumberge et al., 2018), have improved geodetic coverage of the poorly monitored seafloor. Among them, GNSS‐A has been proven suitable for long‐term and long‐distance seafloor displacement monitoring due to its ability to provide vector measurements in a global reference frame, to be free of instrument drift, and to be flexibly deployable in a range of water depths.…”

Section: Introductionmentioning

confidence: 99%

Shallow Water Seafloor Geodesy With Wave Glider‐Based GNSS‐Acoustic Surveying of a Single Transponder

Xie,

Zumberge,

Sasagawa

et al. 2023

Earth and Space Science

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Due to the blockage of seawater, seafloor displacement cannot be directly measured by space geodesy. The combination of Global Navigation Satellite Systems‐acoustic ranging (GNSS‐A) has been used to overcome the electromagnetic barrier, so that a GNSS‐determined sea surface vessel's coordinates can be transformed to seafloor benchmarks in a global reference frame. Due to the high cost and science priorities, previous GNSS‐A studies mainly targeted relatively deep water and a minimum of three transponders were used to form an array, equivalent to a precision geodetic station. With recent developments in unmanned autonomous surface vessels, low cost GNSS‐A surveys are poised to become practical. Here we demonstrate that with a carefully designed surveying trajectory, Wave Glider‐based GNSS‐A surveying of a single transponder in shallow water can provide centimeter‐level accuracy on horizontal seafloor positioning, even if the sound speed model deviates from the actual value by a few meters per second. Results from a nine‐month experiment conducted at ∼54 m water depth show that the repeatability of the seafloor horizontal positioning is better than 2 cm. When conditions allow, the acoustic observations should be collected symmetrically about the transponder and data redundancies are recommended to reduce the error associated with time‐dependent variations in sound speed.

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Calibrated absolute seafloor pressure measurements for geodesy in Cascadia

Cited by 2 publications

References 20 publications

Calibrated Absolute Seafloor Pressure Measurements for Geodesy in Cascadia

Calibrated Absolute Seafloor Pressure Measurements for Geodesy in Cascadia

Shallow Water Seafloor Geodesy With Wave Glider‐Based GNSS‐Acoustic Surveying of a Single Transponder

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