Improve ocean mixing caused by subgrid-scale brine rejection using multi-column ocean grid in a climate model

Heterogeneous ice pack with sporadic narrow but long leads in the polar oceans was unresolved in typical climate model grid. Although multi-category sea ice thickness distribution was used in one sea ice model grid to calculate separate heat, salt and tracer fluxes through each category, the ocean m...

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Bibliographic Details
Format: Dataset
Language:unknown
Published: International Arctic Research Center (IARC) Data Archive
Subjects:
Ice pack
model
long lead
salinity
Arctic Ocean
Arctic
Arctic Basin
ice pack
Sea ice
Online Access:https://search.dataone.org/view/dcx_16913ec3-5e08-45ba-a4d0-77cc94886842_2
id dataone:dcx_16913ec3-5e08-45ba-a4d0-77cc94886842_2
record_format openpolar
spelling dataone:dcx_16913ec3-5e08-45ba-a4d0-77cc94886842_2 2023-11-08T14:14:14+01:00 Improve ocean mixing caused by subgrid-scale brine rejection using multi-column ocean grid in a climate model ENVELOPE(-180.0,180.0,90.0,65.0) 2016-12-23T20:42:28.751Z https://search.dataone.org/view/dcx_16913ec3-5e08-45ba-a4d0-77cc94886842_2 unknown International Arctic Research Center (IARC) Data Archive Ice pack model long lead salinity Arctic Ocean Dataset dataone:urn:node:IARC 2023-11-08T13:39:21Z Heterogeneous ice pack with sporadic narrow but long leads in the polar oceans was unresolved in typical climate model grid. Although multi-category sea ice thickness distribution was used in one sea ice model grid to calculate separate heat, salt and tracer fluxes through each category, the ocean models use only single-column grid to communicate with the averaged fluxes from all categories. When the lead is resolved by the grid, the added salt at the sea surface will sink to the base of the mixed layer and then spread horizontally. When averaged at a climate-model grid size, this vertical distribution of added salt is lead-fraction dependent. When the lead is unresolved, the model errors were systematic leading to greater surface salinity and deeper mixed-layer depth (MLD). An empirical function was developed to revise the added-salt-related parameter n from being fixed to lead-fraction dependent. Application of this new scheme in climate model showed significant improvement in modeled wintertime salinity and MLD as compared to series of CTD data sets in 1997/1998 and 2006/2007. The results showed the most evident improvement in modeled MLD in the Arctic Basin, similar to that using a fixed n = 5, as recommended by the previous Arctic regional model study, in which the parameter n obtained is close to 5 due to the small lead fraction in the Arctic Basin in winter. Dataset Arctic Basin Arctic Arctic Ocean ice pack Sea ice International Arctic Research Center (IARC) Data Archive (via DataONE) Arctic Arctic Ocean ENVELOPE(-180.0,180.0,90.0,65.0)
institution Open Polar
collection International Arctic Research Center (IARC) Data Archive (via DataONE)
op_collection_id dataone:urn:node:IARC
language unknown
topic Ice pack
model
long lead
salinity
Arctic Ocean
spellingShingle Ice pack
model
long lead
salinity
Arctic Ocean
Improve ocean mixing caused by subgrid-scale brine rejection using multi-column ocean grid in a climate model
topic_facet Ice pack
model
long lead
salinity
Arctic Ocean
description Heterogeneous ice pack with sporadic narrow but long leads in the polar oceans was unresolved in typical climate model grid. Although multi-category sea ice thickness distribution was used in one sea ice model grid to calculate separate heat, salt and tracer fluxes through each category, the ocean models use only single-column grid to communicate with the averaged fluxes from all categories. When the lead is resolved by the grid, the added salt at the sea surface will sink to the base of the mixed layer and then spread horizontally. When averaged at a climate-model grid size, this vertical distribution of added salt is lead-fraction dependent. When the lead is unresolved, the model errors were systematic leading to greater surface salinity and deeper mixed-layer depth (MLD). An empirical function was developed to revise the added-salt-related parameter n from being fixed to lead-fraction dependent. Application of this new scheme in climate model showed significant improvement in modeled wintertime salinity and MLD as compared to series of CTD data sets in 1997/1998 and 2006/2007. The results showed the most evident improvement in modeled MLD in the Arctic Basin, similar to that using a fixed n = 5, as recommended by the previous Arctic regional model study, in which the parameter n obtained is close to 5 due to the small lead fraction in the Arctic Basin in winter.
format Dataset
title Improve ocean mixing caused by subgrid-scale brine rejection using multi-column ocean grid in a climate model
title_short Improve ocean mixing caused by subgrid-scale brine rejection using multi-column ocean grid in a climate model
title_full Improve ocean mixing caused by subgrid-scale brine rejection using multi-column ocean grid in a climate model
title_fullStr Improve ocean mixing caused by subgrid-scale brine rejection using multi-column ocean grid in a climate model
title_full_unstemmed Improve ocean mixing caused by subgrid-scale brine rejection using multi-column ocean grid in a climate model
title_sort improve ocean mixing caused by subgrid-scale brine rejection using multi-column ocean grid in a climate model
publisher International Arctic Research Center (IARC) Data Archive
publishDate
url https://search.dataone.org/view/dcx_16913ec3-5e08-45ba-a4d0-77cc94886842_2
op_coverage ENVELOPE(-180.0,180.0,90.0,65.0)
long_lat ENVELOPE(-180.0,180.0,90.0,65.0)
geographic Arctic
Arctic Ocean
geographic_facet Arctic
Arctic Ocean
genre Arctic Basin
Arctic
Arctic Ocean
ice pack
Sea ice
genre_facet Arctic Basin
Arctic
Arctic Ocean
ice pack
Sea ice
_version_ 1782012288685834240

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