Movie 1 from Linking scales in sea ice mechanics
Mechanics plays a key role in the evolution of the sea ice cover through its control on drift, on momentum and thermal energy exchanges between the polar oceans and the atmosphere along cracks and faults, and on ice thickness distribution through opening and ridging processes. At the local scale, a...
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ftroysocietyfig:oai:figshare.com:article/4244591 2023-05-15T18:16:23+02:00 Movie 1 from Linking scales in sea ice mechanics Jérôme Weiss Véronique Dansereau 2016-11-21T11:57:24Z https://doi.org/10.6084/m9.figshare.4244591.v1 https://figshare.com/articles/media/Movie_1_from_Linking_scales_in_sea_ice_mechanics/4244591 unknown doi:10.6084/m9.figshare.4244591.v1 https://figshare.com/articles/media/Movie_1_from_Linking_scales_in_sea_ice_mechanics/4244591 CC BY 4.0 CC-BY Mechanics Glaciology sea ice deformation scaling rheology modelling Dataset Media 2016 ftroysocietyfig https://doi.org/10.6084/m9.figshare.4244591.v1 2022-01-01T19:58:54Z Mechanics plays a key role in the evolution of the sea ice cover through its control on drift, on momentum and thermal energy exchanges between the polar oceans and the atmosphere along cracks and faults, and on ice thickness distribution through opening and ridging processes. At the local scale, a significant variability of the mechanical strength is associated with the microstructural heterogeneity of saline ice, however, characterized by a small correlation length, below the ice thickness scale. Conversely, the sea ice mechanical fields (velocity, strain and stress) are characterized by long-ranged (more than 1000 km) and long-lasting (approx. few months) correlations. The associated space and time scaling laws are the signature of the brittle character of sea ice mechanics, with deformation resulting from a multi-scale accumulation of episodic fracturing and faulting events. To translate the short-range-correlated disorder on strength into long-range-correlated mechanical fields, several key ingredients are identified: long-ranged elastic interactions, slow driving conditions, a slow viscous-like relaxation of elastic stresses and a restoring/healing mechanism. These ingredients constrained the development of a new continuum mechanics modelling framework for the sea ice cover, called Maxwell-elasto-brittle. Idealized simulations without advection demonstrate that this rheological framework reproduces the main characteristics of sea ice mechanics, including anisotropy, spatial localization and intermittency, as well as the associated scaling laws. Dataset Sea ice The Royal Society: Figshare |
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Open Polar |
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The Royal Society: Figshare |
op_collection_id |
ftroysocietyfig |
language |
unknown |
topic |
Mechanics Glaciology sea ice deformation scaling rheology modelling |
spellingShingle |
Mechanics Glaciology sea ice deformation scaling rheology modelling Jérôme Weiss Véronique Dansereau Movie 1 from Linking scales in sea ice mechanics |
topic_facet |
Mechanics Glaciology sea ice deformation scaling rheology modelling |
description |
Mechanics plays a key role in the evolution of the sea ice cover through its control on drift, on momentum and thermal energy exchanges between the polar oceans and the atmosphere along cracks and faults, and on ice thickness distribution through opening and ridging processes. At the local scale, a significant variability of the mechanical strength is associated with the microstructural heterogeneity of saline ice, however, characterized by a small correlation length, below the ice thickness scale. Conversely, the sea ice mechanical fields (velocity, strain and stress) are characterized by long-ranged (more than 1000 km) and long-lasting (approx. few months) correlations. The associated space and time scaling laws are the signature of the brittle character of sea ice mechanics, with deformation resulting from a multi-scale accumulation of episodic fracturing and faulting events. To translate the short-range-correlated disorder on strength into long-range-correlated mechanical fields, several key ingredients are identified: long-ranged elastic interactions, slow driving conditions, a slow viscous-like relaxation of elastic stresses and a restoring/healing mechanism. These ingredients constrained the development of a new continuum mechanics modelling framework for the sea ice cover, called Maxwell-elasto-brittle. Idealized simulations without advection demonstrate that this rheological framework reproduces the main characteristics of sea ice mechanics, including anisotropy, spatial localization and intermittency, as well as the associated scaling laws. |
format |
Dataset |
author |
Jérôme Weiss Véronique Dansereau |
author_facet |
Jérôme Weiss Véronique Dansereau |
author_sort |
Jérôme Weiss |
title |
Movie 1 from Linking scales in sea ice mechanics |
title_short |
Movie 1 from Linking scales in sea ice mechanics |
title_full |
Movie 1 from Linking scales in sea ice mechanics |
title_fullStr |
Movie 1 from Linking scales in sea ice mechanics |
title_full_unstemmed |
Movie 1 from Linking scales in sea ice mechanics |
title_sort |
movie 1 from linking scales in sea ice mechanics |
publishDate |
2016 |
url |
https://doi.org/10.6084/m9.figshare.4244591.v1 https://figshare.com/articles/media/Movie_1_from_Linking_scales_in_sea_ice_mechanics/4244591 |
genre |
Sea ice |
genre_facet |
Sea ice |
op_relation |
doi:10.6084/m9.figshare.4244591.v1 https://figshare.com/articles/media/Movie_1_from_Linking_scales_in_sea_ice_mechanics/4244591 |
op_rights |
CC BY 4.0 |
op_rightsnorm |
CC-BY |
op_doi |
https://doi.org/10.6084/m9.figshare.4244591.v1 |
_version_ |
1766189952525139968 |