Fracture Angles in Numerical Simulations of Sea Ice with Viscous-Plastic Rheologies

Sea ice is an essential component of the climate system because it modulates the exchange of energy between the ocean and the atmosphere. Under stress from wind and ocean currents, sea ice deforms constantly. Sea ice deformation takes the shape of narrow lines, the Linear Kinematic Features (LKFs)....

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Bibliographic Details
Main Author: Ringeisen, Damien
Format: Thesis
Language:English
Published: Universität Bremen 2020
Subjects:
sea ice
rheology
viscous plastic
modelling
arctic
LKF
high-resolution
numerical
simulation
fracture
angles
coulombic
friction
yield curve
plastic potential
flow rule
model
climate
climate change
banquise
ocean
dilatancy
granular
530
Arctic
Teardrop
Climate change
Sea ice
Online Access:https://dx.doi.org/10.26092/elib/380
https://media.suub.uni-bremen.de/handle/elib/4583
id ftdatacite:10.26092/elib/380
record_format openpolar
spelling ftdatacite:10.26092/elib/380 2023-05-15T15:19:50+02:00 Fracture Angles in Numerical Simulations of Sea Ice with Viscous-Plastic Rheologies Ringeisen, Damien 2020 https://dx.doi.org/10.26092/elib/380 https://media.suub.uni-bremen.de/handle/elib/4583 en eng Universität Bremen Attribution 3.0 Germany http://creativecommons.org/licenses/by/3.0/de/ CC-BY sea ice rheology viscous plastic modelling arctic LKF high-resolution numerical simulation fracture angles coulombic friction yield curve plastic potential flow rule model climate climate change banquise ocean dilatancy granular 530 Thesis Other Dissertation thesis 2020 ftdatacite https://doi.org/10.26092/elib/380 2021-11-05T12:55:41Z Sea ice is an essential component of the climate system because it modulates the exchange of energy between the ocean and the atmosphere. Under stress from wind and ocean currents, sea ice deforms constantly. Sea ice deformation takes the shape of narrow lines, the Linear Kinematic Features (LKFs). LKFs influence the heat transfer, mass balance, and sea ice dynamics, so LKFs should be accurately represented in high-resolution climate models. Sea ice is commonly modeled using viscous-plastic (VP) rheologies defined by a yield curve and a flow rule. Recent work showed that VP sea ice models explicitly create LKFs but overestimate their intersection angles. This thesis aims to investigate the link between the angles of fracture in sea ice models and the parametrization of the sea ice internal stresses using idealized compression experiments. Three questions are addressed: Which parameters of the VP rheologies influence the fracture angle? Which theoretical framework explains this influence? Which rheologies should be used to simulate intersection angles at the observed range? With the commonly used standard VP rheology with an elliptical yield curve and a normal flow rule, the fracture angles are linked to the yield curve's elliptical shape. Because of this shape, this rheology cannot create sea ice fracture angles more acute than 30 degrees in uniaxial compression, even by changing the aspect of the ellipse. The classical coulombic theory predicts the angle of fracture accurately when adapted to the context of sea ice modeling. A new rheology with an elliptical yield curve and a non-normal flow rule shows that fracture angles are also sensitive to the orientation of the flow rule. Using this new rheology allows creating fracture angles as low as 22 degrees in uniaxial compression. A theory based on the angle of dilatancy and observations of granular materials predicts precisely the simulated angles. Alternative rheologies can create fracture angles lower than 30 degrees. With Mohr--Coulomb yield curves, fracture angles are well predicted by joining the concepts of coulombic friction and angle of dilatancy. Teardrop and Parabolic lens yield curves create small angles of fracture in uni-axial compression when used with small tensile strength. Using a more realistic sea ice cover with heterogeneity, failure under deformation takes the form of a network of fracture lines. The choice of rheology strongly influences the angle of fracture in this network. Two rheologies are suitable candidates to decrease the fracture angles in sea ice VP models. In conclusion, fracture angles in sea ice models are determined by the properties of the VP rheology and can be accurately predicted using fracture orientation theory. Changing the rheology can reduce the fracture angles in sea ice simulations. With the results presented in this thesis, new rheologies could be inferred from observations to represent sea ice fracture more realistically. Thesis Arctic banquise Climate change Sea ice DataCite Metadata Store (German National Library of Science and Technology) Arctic Teardrop ENVELOPE(163.917,163.917,-78.150,-78.150)
institution Open Polar
collection DataCite Metadata Store (German National Library of Science and Technology)
op_collection_id ftdatacite
language English
topic sea ice
rheology
viscous plastic
modelling
arctic
LKF
high-resolution
numerical
simulation
fracture
angles
coulombic
friction
yield curve
plastic potential
flow rule
model
climate
climate change
banquise
ocean
dilatancy
granular
530
spellingShingle sea ice
rheology
viscous plastic
modelling
arctic
LKF
high-resolution
numerical
simulation
fracture
angles
coulombic
friction
yield curve
plastic potential
flow rule
model
climate
climate change
banquise
ocean
dilatancy
granular
530
Ringeisen, Damien
Fracture Angles in Numerical Simulations of Sea Ice with Viscous-Plastic Rheologies
topic_facet sea ice
rheology
viscous plastic
modelling
arctic
LKF
high-resolution
numerical
simulation
fracture
angles
coulombic
friction
yield curve
plastic potential
flow rule
model
climate
climate change
banquise
ocean
dilatancy
granular
530
description Sea ice is an essential component of the climate system because it modulates the exchange of energy between the ocean and the atmosphere. Under stress from wind and ocean currents, sea ice deforms constantly. Sea ice deformation takes the shape of narrow lines, the Linear Kinematic Features (LKFs). LKFs influence the heat transfer, mass balance, and sea ice dynamics, so LKFs should be accurately represented in high-resolution climate models. Sea ice is commonly modeled using viscous-plastic (VP) rheologies defined by a yield curve and a flow rule. Recent work showed that VP sea ice models explicitly create LKFs but overestimate their intersection angles. This thesis aims to investigate the link between the angles of fracture in sea ice models and the parametrization of the sea ice internal stresses using idealized compression experiments. Three questions are addressed: Which parameters of the VP rheologies influence the fracture angle? Which theoretical framework explains this influence? Which rheologies should be used to simulate intersection angles at the observed range? With the commonly used standard VP rheology with an elliptical yield curve and a normal flow rule, the fracture angles are linked to the yield curve's elliptical shape. Because of this shape, this rheology cannot create sea ice fracture angles more acute than 30 degrees in uniaxial compression, even by changing the aspect of the ellipse. The classical coulombic theory predicts the angle of fracture accurately when adapted to the context of sea ice modeling. A new rheology with an elliptical yield curve and a non-normal flow rule shows that fracture angles are also sensitive to the orientation of the flow rule. Using this new rheology allows creating fracture angles as low as 22 degrees in uniaxial compression. A theory based on the angle of dilatancy and observations of granular materials predicts precisely the simulated angles. Alternative rheologies can create fracture angles lower than 30 degrees. With Mohr--Coulomb yield curves, fracture angles are well predicted by joining the concepts of coulombic friction and angle of dilatancy. Teardrop and Parabolic lens yield curves create small angles of fracture in uni-axial compression when used with small tensile strength. Using a more realistic sea ice cover with heterogeneity, failure under deformation takes the form of a network of fracture lines. The choice of rheology strongly influences the angle of fracture in this network. Two rheologies are suitable candidates to decrease the fracture angles in sea ice VP models. In conclusion, fracture angles in sea ice models are determined by the properties of the VP rheology and can be accurately predicted using fracture orientation theory. Changing the rheology can reduce the fracture angles in sea ice simulations. With the results presented in this thesis, new rheologies could be inferred from observations to represent sea ice fracture more realistically.
format Thesis
author Ringeisen, Damien
author_facet Ringeisen, Damien
author_sort Ringeisen, Damien
title Fracture Angles in Numerical Simulations of Sea Ice with Viscous-Plastic Rheologies
title_short Fracture Angles in Numerical Simulations of Sea Ice with Viscous-Plastic Rheologies
title_full Fracture Angles in Numerical Simulations of Sea Ice with Viscous-Plastic Rheologies
title_fullStr Fracture Angles in Numerical Simulations of Sea Ice with Viscous-Plastic Rheologies
title_full_unstemmed Fracture Angles in Numerical Simulations of Sea Ice with Viscous-Plastic Rheologies
title_sort fracture angles in numerical simulations of sea ice with viscous-plastic rheologies
publisher Universität Bremen
publishDate 2020
url https://dx.doi.org/10.26092/elib/380
https://media.suub.uni-bremen.de/handle/elib/4583
long_lat ENVELOPE(163.917,163.917,-78.150,-78.150)
geographic Arctic
Teardrop
geographic_facet Arctic
Teardrop
genre Arctic
banquise
Climate change
Sea ice
genre_facet Arctic
banquise
Climate change
Sea ice
op_rights Attribution 3.0 Germany
http://creativecommons.org/licenses/by/3.0/de/
op_rightsnorm CC-BY
op_doi https://doi.org/10.26092/elib/380
_version_ 1766350034471747584

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