In situ Sea Ice Experiments in McMurdo Sound: Cyclic Loading, Fracture, and Acoustic Emissions

The breakup of first-year sea ice plays an important role in the dynamics and thermodynamics of polar ice covers. A recent research program has studied the in situ mechanical properties of the annual ice in Antarctica to support the development of physically based models of the breakup process. As p...

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Bibliographic Details
Published inJournal of cold regions engineering Vol. 18; no. 4; pp. 155 - 174
Main Authors Cole, David M, Dempsey, John P
Format Journal Article
LanguageEnglish
Published Reston, VA American Society of Civil Engineers 01.12.2004
Subjects
Earth, ocean, space
Exact sciences and technology
External geophysics
Physics of the oceans
Sea ice
TECHNICAL PAPERS
Antarctica
acoustical emissions
experimental studies
Cold regions
Fracture mechanics
Viscoelastic strain
Ice
Antarctic
in situ
Microcracking
Thermal factors
In situ tests
Cyclic load
sea ice
polar regions
Cold climate
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Summary:The breakup of first-year sea ice plays an important role in the dynamics and thermodynamics of polar ice covers. A recent research program has studied the in situ mechanical properties of the annual ice in Antarctica to support the development of physically based models of the breakup process. As part of this effort, two field trips were conducted to McMurdo Sound, and the present paper describes the experimental work and presents selected results. The in situ experiments investigated the constitutive and fracture behavior of edge-notched, square plate specimens of first-year ice and involved a detailed characterization of the physical properties and thermal state of the ice. Acoustic emissions, which are generated by microcracking, were monitored in the crack tip vicinity and provide insight regarding the size of the process zone. The paper describes the physical properties and microstructure of the sheet, the cyclic-loading response, and the acoustic emissions activity from an extensive series of experiments conducted on one of the in situ specimens. Varying the cyclic-loading frequency and amplitude provided a means to examine rate effects on the anelastic and viscous components of strain and the extent of microcracking near the crack tip. The viscous deformation rate estimated from the experiments exhibited an increasing power-law exponent with values between one and three. Acoustic emissions monitoring indicated that microcracking occurred in a process zone near the crack tip, and the size of the process zone increased with decreasing cyclic loading frequency. Practical aspects of the experiments are considered, and the results are put into context with the overall modeling goals of the project.
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ISSN:0887-381X
1943-5495
DOI:10.1061/(ASCE)0887-381X(2004)18:4(155)