Output from a numerical model of the ocean beneath Larsen C Ice Shelf, Antarctica
This dataset contains output from a hydrodynamic model of the ocean in the Larsen C Ice Shelf (LCIS) cavity and a nearby area of the western Wedell Sea. Simulations were run using the MITgcm numerical ocean model and included an ice shelf with steady thickness. A new LCIS bathymetry was used in the...
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NERC EDS UK Polar Data Centre
2022
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Online Access: | https://dx.doi.org/10.5285/a54c795c-e0ee-49cb-99dd-befbdc4a70f0 https://data.bas.ac.uk/full-record.php?id=GB/NERC/BAS/PDC/01605 |
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ftdatacite:10.5285/a54c795c-e0ee-49cb-99dd-befbdc4a70f0 2023-05-15T14:02:16+02:00 Output from a numerical model of the ocean beneath Larsen C Ice Shelf, Antarctica Harrison, Lianne 2022 application/x-hdf https://dx.doi.org/10.5285/a54c795c-e0ee-49cb-99dd-befbdc4a70f0 https://data.bas.ac.uk/full-record.php?id=GB/NERC/BAS/PDC/01605 en eng NERC EDS UK Polar Data Centre https://github.com/lianneharrisonBAS/LCIS_paper https://github.com/MITgcm/ https://www.esr.org/research/polar-tide-models/list-of-polar-tide-models/cats2008/ Open Government Licence V3.0 http://www.nationalarchives.gov.uk/doc/open-government-licence/version/3/ "EARTH SCIENCE","OCEANS","SEA ICE","ICE GROWTH/MELT" "EARTH SCIENCE","OCEANS","MARINE ENVIRONMENT MONITORING" Ice shelf-ocean interactions Larsen C Ice Shelf Marine ice Model validation Ocean warming experiments Ice shelf-ocean interactions,Larsen C Ice Shelf,Marine ice,Model validation,Ocean warming experiments Dataset dataset 2022 ftdatacite https://doi.org/10.5285/a54c795c-e0ee-49cb-99dd-befbdc4a70f0 2022-03-10T10:38:39Z This dataset contains output from a hydrodynamic model of the ocean in the Larsen C Ice Shelf (LCIS) cavity and a nearby area of the western Wedell Sea. Simulations were run using the MITgcm numerical ocean model and included an ice shelf with steady thickness. A new LCIS bathymetry was used in the simulations, referred to as the 'Brisbourne' bathymetry. The data provided here includes these geometry grids and ocean velocity and basal melt rate fields output from the final year of an arbitrary 10-year simulation, or a 6-month extension run. Calculated marine ice fields beneath the ice shelf based on the simulation's melt rate results are also included. In addition, output from several simulations using different initial and boundary ocean temperature conditions and runs with different cavity geometries are also provided. This work was supported by the Natural Environment Research Council and the EnvEast Doctoral Training Partnership [grant number NE/L002582/1] and PICCOLO [grant number NE/P021395/1]. : Simulations were run using the MITgcm numerical ocean model, version c65z. The model featured an ice shelf with steady thickness and a new bathymetry created using natural neighbour interpolation of 114 seismic soundings in the LCIS cavity. The bathymetry was deepened to create a minimum water-column thickness of 40 m, the thickness of two full grid cells, to allow unhindered flow wherever the ice is known to be floating. The domain included the LCIS cavity and a small area of the western Weddell Sea, with a uniform grid resolution of 20 m in the vertical, 1/20° in longitude, and variable in latitude, scaled by the cosine of the latitude, resulting in isotropic grid cells of ~2 km width. Constant diffusivities of 10 m2/s in the horizontal and 10-4 m2/s in the vertical were used, and lateral and vertical eddy viscosity coefficients of 50 m2/s and 10-3 m2/s, respectively. A three-equation model was used to parameterise melting and freezing, with a drag coefficient of 0.0022 and heat and salt transfer coefficients of 0.011 and 3.1 x 10-4, respectively. Tides were implemented by imposing velocities on open boundaries to the north, east and south from the CATS2008 inverse tidal model. Constant ocean properties were imposed on the model boundaries with a potential temperature of -1.9 °C and practical salinity of 34.5, the same values as the initial conditions. Further simulations with initial and boundary condition temperatures of -1.8 °C, -1.6 °C, and -1.4 °C were also run, as well as alternative bathymetry simulations. The marine ice fields were calculated by assuming that modelled melt/freeze rates, and ice shelf velocities are fixed in time. These fields were interpolated onto a 100 m grid and then marine ice thickness was time-stepped on this grid for 500 years using a simple upwind advection scheme. Dataset Antarc* Antarctica Ice Shelf Sea ice Weddell Sea DataCite Metadata Store (German National Library of Science and Technology) Weddell Sea Weddell |
institution |
Open Polar |
collection |
DataCite Metadata Store (German National Library of Science and Technology) |
op_collection_id |
ftdatacite |
language |
English |
topic |
"EARTH SCIENCE","OCEANS","SEA ICE","ICE GROWTH/MELT" "EARTH SCIENCE","OCEANS","MARINE ENVIRONMENT MONITORING" Ice shelf-ocean interactions Larsen C Ice Shelf Marine ice Model validation Ocean warming experiments |
spellingShingle |
"EARTH SCIENCE","OCEANS","SEA ICE","ICE GROWTH/MELT" "EARTH SCIENCE","OCEANS","MARINE ENVIRONMENT MONITORING" Ice shelf-ocean interactions Larsen C Ice Shelf Marine ice Model validation Ocean warming experiments Harrison, Lianne Output from a numerical model of the ocean beneath Larsen C Ice Shelf, Antarctica |
topic_facet |
"EARTH SCIENCE","OCEANS","SEA ICE","ICE GROWTH/MELT" "EARTH SCIENCE","OCEANS","MARINE ENVIRONMENT MONITORING" Ice shelf-ocean interactions Larsen C Ice Shelf Marine ice Model validation Ocean warming experiments |
description |
This dataset contains output from a hydrodynamic model of the ocean in the Larsen C Ice Shelf (LCIS) cavity and a nearby area of the western Wedell Sea. Simulations were run using the MITgcm numerical ocean model and included an ice shelf with steady thickness. A new LCIS bathymetry was used in the simulations, referred to as the 'Brisbourne' bathymetry. The data provided here includes these geometry grids and ocean velocity and basal melt rate fields output from the final year of an arbitrary 10-year simulation, or a 6-month extension run. Calculated marine ice fields beneath the ice shelf based on the simulation's melt rate results are also included. In addition, output from several simulations using different initial and boundary ocean temperature conditions and runs with different cavity geometries are also provided. This work was supported by the Natural Environment Research Council and the EnvEast Doctoral Training Partnership [grant number NE/L002582/1] and PICCOLO [grant number NE/P021395/1]. : Simulations were run using the MITgcm numerical ocean model, version c65z. The model featured an ice shelf with steady thickness and a new bathymetry created using natural neighbour interpolation of 114 seismic soundings in the LCIS cavity. The bathymetry was deepened to create a minimum water-column thickness of 40 m, the thickness of two full grid cells, to allow unhindered flow wherever the ice is known to be floating. The domain included the LCIS cavity and a small area of the western Weddell Sea, with a uniform grid resolution of 20 m in the vertical, 1/20° in longitude, and variable in latitude, scaled by the cosine of the latitude, resulting in isotropic grid cells of ~2 km width. Constant diffusivities of 10 m2/s in the horizontal and 10-4 m2/s in the vertical were used, and lateral and vertical eddy viscosity coefficients of 50 m2/s and 10-3 m2/s, respectively. A three-equation model was used to parameterise melting and freezing, with a drag coefficient of 0.0022 and heat and salt transfer coefficients of 0.011 and 3.1 x 10-4, respectively. Tides were implemented by imposing velocities on open boundaries to the north, east and south from the CATS2008 inverse tidal model. Constant ocean properties were imposed on the model boundaries with a potential temperature of -1.9 °C and practical salinity of 34.5, the same values as the initial conditions. Further simulations with initial and boundary condition temperatures of -1.8 °C, -1.6 °C, and -1.4 °C were also run, as well as alternative bathymetry simulations. The marine ice fields were calculated by assuming that modelled melt/freeze rates, and ice shelf velocities are fixed in time. These fields were interpolated onto a 100 m grid and then marine ice thickness was time-stepped on this grid for 500 years using a simple upwind advection scheme. |
format |
Dataset |
author |
Harrison, Lianne |
author_facet |
Harrison, Lianne |
author_sort |
Harrison, Lianne |
title |
Output from a numerical model of the ocean beneath Larsen C Ice Shelf, Antarctica |
title_short |
Output from a numerical model of the ocean beneath Larsen C Ice Shelf, Antarctica |
title_full |
Output from a numerical model of the ocean beneath Larsen C Ice Shelf, Antarctica |
title_fullStr |
Output from a numerical model of the ocean beneath Larsen C Ice Shelf, Antarctica |
title_full_unstemmed |
Output from a numerical model of the ocean beneath Larsen C Ice Shelf, Antarctica |
title_sort |
output from a numerical model of the ocean beneath larsen c ice shelf, antarctica |
publisher |
NERC EDS UK Polar Data Centre |
publishDate |
2022 |
url |
https://dx.doi.org/10.5285/a54c795c-e0ee-49cb-99dd-befbdc4a70f0 https://data.bas.ac.uk/full-record.php?id=GB/NERC/BAS/PDC/01605 |
geographic |
Weddell Sea Weddell |
geographic_facet |
Weddell Sea Weddell |
genre |
Antarc* Antarctica Ice Shelf Sea ice Weddell Sea |
genre_facet |
Antarc* Antarctica Ice Shelf Sea ice Weddell Sea |
op_relation |
https://github.com/lianneharrisonBAS/LCIS_paper https://github.com/MITgcm/ https://www.esr.org/research/polar-tide-models/list-of-polar-tide-models/cats2008/ |
op_rights |
Open Government Licence V3.0 http://www.nationalarchives.gov.uk/doc/open-government-licence/version/3/ |
op_doi |
https://doi.org/10.5285/a54c795c-e0ee-49cb-99dd-befbdc4a70f0 |
_version_ |
1766272427447287808 |