XBTs Provide First‐Order Characterization of Seabed Physical Properties

Matthew J. Hornbach; Warren T. Wood; Taylor R. Lee; Benjamin J. Phrampus; Andrei Abelev; Peter C. Herdic; Emma Woodford; Samuel S. Griffith; Stephanie M. Dohner; Edward F. Braithwaite III

doi:10.1029/2023EA003441

Earth and Space Science (Aug 2024)

XBTs Provide First‐Order Characterization of Seabed Physical Properties

Matthew J. Hornbach,
Warren T. Wood,
Taylor R. Lee,
Benjamin J. Phrampus,
Andrei Abelev,
Peter C. Herdic,
Emma Woodford,
Samuel S. Griffith,
Stephanie M. Dohner,
Edward F. Braithwaite III

Affiliations

Matthew J. Hornbach: U.S. Naval Research Laboratory Ocean Sciences Division Stennis Space Center MS USA
Warren T. Wood: U.S. Naval Research Laboratory Ocean Sciences Division Stennis Space Center MS USA
Taylor R. Lee: U.S. Naval Research Laboratory Ocean Sciences Division Stennis Space Center MS USA
Benjamin J. Phrampus: U.S. Naval Research Laboratory Ocean Sciences Division Stennis Space Center MS USA
Andrei Abelev: U.S. Naval Research Laboratory Remote Sensing Division Washington DC USA
Peter C. Herdic: U.S. Naval Research Laboratory Acoustics Division Washington DC USA
Emma Woodford: U.S. Naval Research Laboratory Acoustics Division Washington DC USA
Samuel S. Griffith: U.S. Naval Research Laboratory Ocean Sciences Division Stennis Space Center MS USA
Stephanie M. Dohner: U.S. Naval Research Laboratory Ocean Sciences Division Stennis Space Center MS USA
Edward F. Braithwaite III: U.S. Naval Research Laboratory Ocean Sciences Division Stennis Space Center MS USA

DOI: https://doi.org/10.1029/2023EA003441
Journal volume & issue: Vol. 11, no. 8
pp. n/a – n/a

Abstract

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Abstract Expendable Bathythermographs (XBTs) are oceanographic instruments that fall through the ocean's water column and measure ocean temperature with depth. In many instances, however, XBTs continue to record temperature after they impact the seabed. Here we show evidence that XBTs produce unique temperature responses when they impact the seabed that depend directly on seabed physical properties. Specifically, standard‐use XBTs (e.g., T‐4s and T‐5s), when deployed above a mud‐rich seabed, require significant time (tens of minutes) to equilibrate to steady‐state seafloor temperatures after seabed impact. In contrast, XBTs deployed above sand‐rich sediments equilibrate to seabed temperatures rapidly (644k XBT measurements exist publicly (via the National Oceanographic and Atmospheric Administration website), and >74,000 XBTs record temperatures post seabed impact, we suggest that XBT data represents a large, low‐cost, and currently untapped data set for characterizing seabed physical properties globally.

Published in Earth and Space Science

ISSN: 2333-5084 (Online)
Publisher: American Geophysical Union (AGU)
Country of publisher: United States
LCC subjects: Science: Astronomy; Science: Geology
Website: https://agupubs.onlinelibrary.wiley.com/journal/23335084

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