Development of a Large-Scale Coupled Sea-Ice Model for Interannual Simulations of Ice Cover in the Arctic

A coupled ice-ocean numerical model is developed which improves the simulation of the annual cycle and interannual variations in ice cover in the Arctic. Although the accuracy of the simulated ice concentration is increased, the annual cycle of ice coverage is still exaggerated. Several experiments...

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Bibliographic Details
Main Author: Fleming, Gordon H.
Other Authors: NAVAL POSTGRADUATE SCHOOL MONTEREY CA
Format: Text
Language:English
Published: 1989
Subjects:
Snow
Ice and Permafrost
*ICE FORECASTING
*OCEAN MODELS
*ARCTIC REGIONS
*SEA ICE
OCEAN CURRENTS
EDGES
ACCURACY
THESES
SENSITIVITY
SURFACES
MATHEMATICAL PREDICTION
CONCENTRATION(COMPOSITION)
COVERINGS
HEAT
HEAT FLUX
SUBSURFACE
ALBEDO
THICKNESS
SIMULATION
PACK ICE
MATHEMATICAL MODELS
COUPLING(INTERACTION)
Arctic
albedo
Ice
ice pack
permafrost
Sea ice
Online Access:http://www.dtic.mil/docs/citations/ADA223670
http://oai.dtic.mil/oai/oai?&verb=getRecord&metadataPrefix=html&identifier=ADA223670
Description
Summary:A coupled ice-ocean numerical model is developed which improves the simulation of the annual cycle and interannual variations in ice cover in the Arctic. Although the accuracy of the simulated ice concentration is increased, the annual cycle of ice coverage is still exaggerated. Several experiments are conducted to determine the importance of incorporating a fully interactive ocean. Inclusion of a fully prognostic ocean component vice a ten-year mean ocean cycle in the model improves the correlation of simulated ice concentration fields with observed data. This is the case for all regions in the Arctic; for both the annual cycle and interannual variations of the ice cover. In contrast to results using ice models without a fully prognostic ocean component, this model is quite insensitive to changes in the frozen surface albedo. Exceptions are evident where the ocean heat flux into the mixed layer is small and the ice is thin. At the spatial (110 km) and temporal (monthly) scales used here, the heat provided by the ocean appears to be the dominant mechanism controlling the position of the ice edge and the extent of the ice pack. Within the pack, it is the dynamic forcing and, in particular, the wind forcing which controls the ice thickness and thickness distribution. The ocean circulation below the mixed layer appears to position the heat underneath the MIZ. The MIZ is also the region where the ice thickness tends to decrease through divergence. The linkage between the subsurface heat and the thinned ice cover is apparently controlled by conditions at the surface and the resulting response of the mixed layer. Keywords: Theses; Arctic regions; Sea ice; Mathematical models/prediction; Ice forecasting; Ocean models.

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