Sea ice floe size:its impact on pan-Arctic and local ice mass, and required model complexity

Sea ice is composed of discrete units called floes. The size of these floes can determine the nature and magnitude of interactions between the sea ice, ocean, and atmosphere including lateral melt rate, momentum and heat exchange, and surface moisture flux. Large-scale geophysical sea ice models emp...

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Main Authors: Bateson, Adam, Feltham, Daniel, Schroder, David, Wang, Yanan, Hwang, Byongjun (Phil), Ridley, Jeff, Aksenov, Yevgeny
Format: Report
Language:English
Published: Copernicus GmbH 2021
Subjects:
Arctic
Sea ice
Online Access:https://pure.hud.ac.uk/en/publications/f933cbbf-7295-40fb-98b6-5e5dfed80cc6
https://doi.org/10.5194/tc-2021-217
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spelling ftuhuddersfieldc:oai:pure.atira.dk:publications/f933cbbf-7295-40fb-98b6-5e5dfed80cc6 2023-05-15T14:24:48+02:00 Sea ice floe size:its impact on pan-Arctic and local ice mass, and required model complexity Bateson, Adam Feltham, Daniel Schroder, David Wang, Yanan Hwang, Byongjun (Phil) Ridley, Jeff Aksenov, Yevgeny 2021-09-08 https://pure.hud.ac.uk/en/publications/f933cbbf-7295-40fb-98b6-5e5dfed80cc6 https://doi.org/10.5194/tc-2021-217 eng eng Copernicus GmbH info:eu-repo/semantics/openAccess Bateson , A , Feltham , D , Schroder , D , Wang , Y , Hwang , B , Ridley , J & Aksenov , Y 2021 ' Sea ice floe size : its impact on pan-Arctic and local ice mass, and required model complexity ' Cryosphere Discussions , Copernicus GmbH . https://doi.org/10.5194/tc-2021-217 workingPaper 2021 ftuhuddersfieldc https://doi.org/10.5194/tc-2021-217 2023-02-05T14:28:37Z Sea ice is composed of discrete units called floes. The size of these floes can determine the nature and magnitude of interactions between the sea ice, ocean, and atmosphere including lateral melt rate, momentum and heat exchange, and surface moisture flux. Large-scale geophysical sea ice models employ a continuum approach and traditionally either assume floes adopt a constant size or do not include an explicit treatment of floe size. Observations show that floes can adopt a range of sizes spanning orders of magnitude, from metres to tens of kilometres. In this study we apply novel observations to analyse two alternative approaches to modelling a floe size distribution (FSD) within the state-of-the-art CICE sea ice model. The first model considered, the WIPoFSD (Waves-in-Ice module and Power law Floe Size Distribution) model, assumes floe size follows a power law with a constant exponent. The second is a prognostic floe size-thickness distribution where the shape of the distribution is an emergent feature of the model and is not assumed a priori. We demonstrate that a parameterisation of in-plane brittle fracture processes should be included in the prognostic model. While neither FSD model results in a significant improvement in the ability of CICE to simulate pan-Arctic metrics in a stand-alone sea ice configuration, larger impacts can be seen over regional scales in sea ice concentration and thickness. We find that the prognostic model particularly enhances sea ice melt in the early melt season, whereas for the WIPoFSD model this melt increase occurs primarily during the late melt season. We then show that these differences between the two FSD models can be explained by considering the effective floe size, a metric used to characterise a given FSD. Finally, we discuss the advantages and disadvantages to these different approaches to modelling the FSD. We note that the WIPoFSD model is less computationally expensive than the prognostic model and produces a better fit to novel FSD observations derived from 2-m ... Report Arctic Arctic Sea ice University of Huddersfield Research Portal Arctic
institution Open Polar
collection University of Huddersfield Research Portal
op_collection_id ftuhuddersfieldc
language English
description Sea ice is composed of discrete units called floes. The size of these floes can determine the nature and magnitude of interactions between the sea ice, ocean, and atmosphere including lateral melt rate, momentum and heat exchange, and surface moisture flux. Large-scale geophysical sea ice models employ a continuum approach and traditionally either assume floes adopt a constant size or do not include an explicit treatment of floe size. Observations show that floes can adopt a range of sizes spanning orders of magnitude, from metres to tens of kilometres. In this study we apply novel observations to analyse two alternative approaches to modelling a floe size distribution (FSD) within the state-of-the-art CICE sea ice model. The first model considered, the WIPoFSD (Waves-in-Ice module and Power law Floe Size Distribution) model, assumes floe size follows a power law with a constant exponent. The second is a prognostic floe size-thickness distribution where the shape of the distribution is an emergent feature of the model and is not assumed a priori. We demonstrate that a parameterisation of in-plane brittle fracture processes should be included in the prognostic model. While neither FSD model results in a significant improvement in the ability of CICE to simulate pan-Arctic metrics in a stand-alone sea ice configuration, larger impacts can be seen over regional scales in sea ice concentration and thickness. We find that the prognostic model particularly enhances sea ice melt in the early melt season, whereas for the WIPoFSD model this melt increase occurs primarily during the late melt season. We then show that these differences between the two FSD models can be explained by considering the effective floe size, a metric used to characterise a given FSD. Finally, we discuss the advantages and disadvantages to these different approaches to modelling the FSD. We note that the WIPoFSD model is less computationally expensive than the prognostic model and produces a better fit to novel FSD observations derived from 2-m ...
format Report
author Bateson, Adam
Feltham, Daniel
Schroder, David
Wang, Yanan
Hwang, Byongjun (Phil)
Ridley, Jeff
Aksenov, Yevgeny
spellingShingle Bateson, Adam
Feltham, Daniel
Schroder, David
Wang, Yanan
Hwang, Byongjun (Phil)
Ridley, Jeff
Aksenov, Yevgeny
Sea ice floe size:its impact on pan-Arctic and local ice mass, and required model complexity
author_facet Bateson, Adam
Feltham, Daniel
Schroder, David
Wang, Yanan
Hwang, Byongjun (Phil)
Ridley, Jeff
Aksenov, Yevgeny
author_sort Bateson, Adam
title Sea ice floe size:its impact on pan-Arctic and local ice mass, and required model complexity
title_short Sea ice floe size:its impact on pan-Arctic and local ice mass, and required model complexity
title_full Sea ice floe size:its impact on pan-Arctic and local ice mass, and required model complexity
title_fullStr Sea ice floe size:its impact on pan-Arctic and local ice mass, and required model complexity
title_full_unstemmed Sea ice floe size:its impact on pan-Arctic and local ice mass, and required model complexity
title_sort sea ice floe size:its impact on pan-arctic and local ice mass, and required model complexity
publisher Copernicus GmbH
publishDate 2021
url https://pure.hud.ac.uk/en/publications/f933cbbf-7295-40fb-98b6-5e5dfed80cc6
https://doi.org/10.5194/tc-2021-217
geographic Arctic
geographic_facet Arctic
genre Arctic
Arctic
Sea ice
genre_facet Arctic
Arctic
Sea ice
op_source Bateson , A , Feltham , D , Schroder , D , Wang , Y , Hwang , B , Ridley , J & Aksenov , Y 2021 ' Sea ice floe size : its impact on pan-Arctic and local ice mass, and required model complexity ' Cryosphere Discussions , Copernicus GmbH . https://doi.org/10.5194/tc-2021-217
op_rights info:eu-repo/semantics/openAccess
op_doi https://doi.org/10.5194/tc-2021-217
_version_ 1766297260146032640

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