A Bayesian Approach for Inferring Sea Ice Loads

The Earth's climate is rapidly changing and some of the most drastic changes can be seen in the Arctic, where sea ice extent has diminished considerably in recent years. As the Arctic climate continues to change, gathering in situ sea ice measurements is increasingly important for understanding...

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Bibliographic Details
Published in:arXiv.org 2021-02
Main Authors: Parno, Matthew, Taylor Hodgdon, West, Brendan, O'Connor, Devin, Song, Arnold
Format: Article
Language:English
Subjects:
Bayesian analysis
Buoys
Climate change
Finite element method
Formability
Ice loads
Residual stress
Sea ice
Statistical inference
Strain gauges
Online Access:Get full text
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Summary:The Earth's climate is rapidly changing and some of the most drastic changes can be seen in the Arctic, where sea ice extent has diminished considerably in recent years. As the Arctic climate continues to change, gathering in situ sea ice measurements is increasingly important for understanding the complex evolution of the Arctic ice pack. To date, observations of ice stresses in the Arctic have been spatially and temporally sparse. We propose a measurement framework that would instrument existing sea ice buoys with strain gauges. This measurement framework uses a Bayesian inference approach to infer ice loads acting on the buoy from a set of strain gauge measurements. To test our framework, strain measurements were collected from an experiment where a buoy was frozen into ice that was subsequently compressed to simulate convergent sea ice conditions. A linear elastic finite element model was used to describe the response of the deformable buoy to mechanical loading, allowing us to link the observed strain on the buoy interior to the applied load on the buoy exterior. The approach presented in this paper presents an instrumentation framework that could use existing buoy platforms as in situ sensors of internal stresses in the ice pack.
ISSN:2331-8422
DOI:10.48550/arxiv.2102.08444