Observing Wind-Forced Flexural-Gravity Waves in the Beaufort Sea and Their Relationship to Sea Ice Mechanics

We developed and deployed two inertial measurement units on mobile pack ice during a U.S. Navy drifting ice campaign in the Beaufort Sea. The ice camp was more than 1000 km from the nearest open water. The sensors were stationed on thick (>1 m) first- and multi–year ice to record 3-D acceleration...

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Bibliographic Details
Published in:Journal of Marine Science and Engineering
Main Authors: Mark A. Johnson, Aleksey V. Marchenko, Dyre O. Dammann, Andrew R. Mahoney
Format: Article in Journal/Newspaper
Language:English
Published: MDPI AG 2021
Subjects:
sea ice
flexural-gravity waves
inertial motion units
Naval architecture. Shipbuilding. Marine engineering
VM1-989
Oceanography
GC1-1581
Beaufort Sea
Sea ice
Online Access:https://doi.org/10.3390/jmse9050471
https://doaj.org/article/5354a80e12c14742b711a0f60c4cb664
Description
Summary:We developed and deployed two inertial measurement units on mobile pack ice during a U.S. Navy drifting ice campaign in the Beaufort Sea. The ice camp was more than 1000 km from the nearest open water. The sensors were stationed on thick (>1 m) first- and multi–year ice to record 3-D accelerations at 10 Hz for one week during March 2020. During this time, gale-force winds exceeded 21 m per second for several hours during two separate wind events and reached a maximum of 25 m per second. Our observations show similar sets of wave bands were excited during both wind events. One band was centered on a period of ~14 s. Another band arrived several hours later and was centered on ~3.5-s. We find that the observed wave bands match a model dispersion curve for flexural gravity waves in ~1.2-m ice with a Young’s modulus of 3.5 GPa under compressive stresses of ~0.3 MPa. We further evaluate the bending stress and load cycles of the individual wave bands and their potential role in break-up of sea ice. This work demonstrates how observations of waves in sea ice using these and similar sensors can potentially be a valuable field-based tool for evaluating ice mechanics. In particular, this approach can be used to observe and describe the combined mechanical behavior of consolidated floes relevant for understanding sea ice mechanical processes and model development.

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