The Effects of Ice Floe-Floe Interactions on Pressure Ridging in Sea Ice

A. Damsgaard; O. Sergienko; A. Adcroft

doi:10.1029/2020MS002336

The Effects of Ice Floe-Floe Interactions on Pressure Ridging in Sea Ice

A. Damsgaard, O. Sergienko, A. Adcroft

Atmospheric & Oceanic Sciences

Research output: Contribution to journal › Article › peer-review

5 Scopus citations

Abstract

The mechanical interactions between ice floes in the polar sea-ice packs play an important role in the state and predictability of the sea-ice cover. We use a Lagrangian-based numerical model to investigate such floe-floe interactions. Our simulations show that elastic and reversible deformation offers significant resistance to compression before ice floes yield with brittle failure. Compressional strength dramatically decreases once pressure ridges start to form, which implies that thicker sea ice is not necessarily stronger than thinner ice. The mechanical transition is not accounted for in most current sea-ice models that describe ice strength by thickness alone. We propose a parameterization that describes failure mechanics from fracture toughness and Coulomb sliding, improving the representation of ridge building dynamics in particle-based and continuum sea-ice models.

Original language	English (US)
Article number	e2020MS002336
Journal	Journal of Advances in Modeling Earth Systems
Volume	13
Issue number	7
DOIs	https://doi.org/10.1029/2020MS002336
State	Published - Jul 2021

All Science Journal Classification (ASJC) codes

Global and Planetary Change
Environmental Chemistry
General Earth and Planetary Sciences

Keywords

discrete element method
numerical modeling
rafting
ridging
sea ice

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10.1029/2020MS002336

Cite this

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title = "The Effects of Ice Floe-Floe Interactions on Pressure Ridging in Sea Ice",

abstract = "The mechanical interactions between ice floes in the polar sea-ice packs play an important role in the state and predictability of the sea-ice cover. We use a Lagrangian-based numerical model to investigate such floe-floe interactions. Our simulations show that elastic and reversible deformation offers significant resistance to compression before ice floes yield with brittle failure. Compressional strength dramatically decreases once pressure ridges start to form, which implies that thicker sea ice is not necessarily stronger than thinner ice. The mechanical transition is not accounted for in most current sea-ice models that describe ice strength by thickness alone. We propose a parameterization that describes failure mechanics from fracture toughness and Coulomb sliding, improving the representation of ridge building dynamics in particle-based and continuum sea-ice models.",

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T1 - The Effects of Ice Floe-Floe Interactions on Pressure Ridging in Sea Ice

AU - Damsgaard, A.

AU - Sergienko, O.

AU - Adcroft, A.

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AB - The mechanical interactions between ice floes in the polar sea-ice packs play an important role in the state and predictability of the sea-ice cover. We use a Lagrangian-based numerical model to investigate such floe-floe interactions. Our simulations show that elastic and reversible deformation offers significant resistance to compression before ice floes yield with brittle failure. Compressional strength dramatically decreases once pressure ridges start to form, which implies that thicker sea ice is not necessarily stronger than thinner ice. The mechanical transition is not accounted for in most current sea-ice models that describe ice strength by thickness alone. We propose a parameterization that describes failure mechanics from fracture toughness and Coulomb sliding, improving the representation of ridge building dynamics in particle-based and continuum sea-ice models.

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KW - ridging

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The Effects of Ice Floe-Floe Interactions on Pressure Ridging in Sea Ice

Abstract

All Science Journal Classification (ASJC) codes

Keywords

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