Advances in Modeling Interactions Between Sea Ice and Ocean Surface Waves

Abstract Recent field programs have highlighted the importance of the composite nature of the sea ice mosaic to the climate system. Accordingly, we previously developed a process‐based prognostic model that captures key characteristics of the sea ice floe size distribution and its evolution subject...

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Main Authors: Lettie A. Roach, Cecilia M. Bitz, Christopher Horvat, Samuel M. Dean
Format: Article
Language:English
Published: American Geophysical Union (AGU) 2019-12-01
Series:Journal of Advances in Modeling Earth Systems
Online Access:https://doi.org/10.1029/2019MS001836
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spelling doaj-2deee09d3fbf45298668afcef3a684672020-11-24T22:07:34ZengAmerican Geophysical Union (AGU)Journal of Advances in Modeling Earth Systems1942-24662019-12-0111124167418110.1029/2019MS001836Advances in Modeling Interactions Between Sea Ice and Ocean Surface WavesLettie A. Roach0Cecilia M. Bitz1Christopher Horvat2Samuel M. Dean3Now at Atmospheric Sciences University of Washington Seattle WA USAAtmospheric Sciences University of Washington Seattle WA USAInstitute at Brown for Environment and Society Brown University Providence RI USANational Climate Centre National Institute of Water and Atmospheric Research Wellington New ZealandAbstract Recent field programs have highlighted the importance of the composite nature of the sea ice mosaic to the climate system. Accordingly, we previously developed a process‐based prognostic model that captures key characteristics of the sea ice floe size distribution and its evolution subject to melting, freezing, new ice formation, welding, and fracture by ocean surface waves. Here we build upon this earlier work, demonstrating a new coupling between the sea ice model and ocean surface waves and a new physically based parameterization for new ice formation in open water. The experiments presented here are the first to include two‐way interactions between prognostically evolving waves and sea ice on a global domain. The simulated area‐average floe perimeter has a similar magnitude to existing observations in the Arctic and exhibits plausible spatial variability. During the melt season, wave fracture is the dominant FSD process driving changes in floe perimeter per unit sea ice area—the quantity that determines the concentration change due to lateral melt—highlighting the importance of wave‐ice interactions for marginal ice zone thermodynamics. We additionally interpret the results to target spatial scales and processes for which floe size observations can most effectively improve model fidelity.https://doi.org/10.1029/2019MS001836
collection DOAJ
language English
format Article
sources DOAJ
author Lettie A. Roach
Cecilia M. Bitz
Christopher Horvat
Samuel M. Dean
spellingShingle Lettie A. Roach
Cecilia M. Bitz
Christopher Horvat
Samuel M. Dean
Advances in Modeling Interactions Between Sea Ice and Ocean Surface Waves
Journal of Advances in Modeling Earth Systems
author_facet Lettie A. Roach
Cecilia M. Bitz
Christopher Horvat
Samuel M. Dean
author_sort Lettie A. Roach
title Advances in Modeling Interactions Between Sea Ice and Ocean Surface Waves
title_short Advances in Modeling Interactions Between Sea Ice and Ocean Surface Waves
title_full Advances in Modeling Interactions Between Sea Ice and Ocean Surface Waves
title_fullStr Advances in Modeling Interactions Between Sea Ice and Ocean Surface Waves
title_full_unstemmed Advances in Modeling Interactions Between Sea Ice and Ocean Surface Waves
title_sort advances in modeling interactions between sea ice and ocean surface waves
publisher American Geophysical Union (AGU)
series Journal of Advances in Modeling Earth Systems
issn 1942-2466
publishDate 2019-12-01
description Abstract Recent field programs have highlighted the importance of the composite nature of the sea ice mosaic to the climate system. Accordingly, we previously developed a process‐based prognostic model that captures key characteristics of the sea ice floe size distribution and its evolution subject to melting, freezing, new ice formation, welding, and fracture by ocean surface waves. Here we build upon this earlier work, demonstrating a new coupling between the sea ice model and ocean surface waves and a new physically based parameterization for new ice formation in open water. The experiments presented here are the first to include two‐way interactions between prognostically evolving waves and sea ice on a global domain. The simulated area‐average floe perimeter has a similar magnitude to existing observations in the Arctic and exhibits plausible spatial variability. During the melt season, wave fracture is the dominant FSD process driving changes in floe perimeter per unit sea ice area—the quantity that determines the concentration change due to lateral melt—highlighting the importance of wave‐ice interactions for marginal ice zone thermodynamics. We additionally interpret the results to target spatial scales and processes for which floe size observations can most effectively improve model fidelity.
url https://doi.org/10.1029/2019MS001836
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AT ceciliambitz advancesinmodelinginteractionsbetweenseaiceandoceansurfacewaves
AT christopherhorvat advancesinmodelinginteractionsbetweenseaiceandoceansurfacewaves
AT samuelmdean advancesinmodelinginteractionsbetweenseaiceandoceansurfacewaves
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