Numerical investigation of the Arctic ice–ocean boundary layer and implications for air–sea gas fluxes
In ice-covered regions it is challenging to determine constituent budgets – for heat and momentum, but also for biologically and climatically active gases like carbon dioxide and methane. The harsh environment and relative data scarcity make it difficult to characterize even the physical properties...
| Published in: | Ocean Science |
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| Format: | Article in Journal/Newspaper |
| Language: | English |
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Copernicus Publications
2017
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| Online Access: | https://doi.org/10.5194/os-13-61-2017 http://www.ocean-sci.net/13/61/2017/os-13-61-2017.pdf https://doaj.org/article/c41d356270bd49a6bc43382ebc5453ce |
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fttriple:oai:gotriple.eu:oai:doaj.org/article:c41d356270bd49a6bc43382ebc5453ce 2023-05-15T15:17:42+02:00 Numerical investigation of the Arctic ice–ocean boundary layer and implications for air–sea gas fluxes A. Bigdeli B. Loose A. T. Nguyen S. T. Cole 2017-01-01 https://doi.org/10.5194/os-13-61-2017 http://www.ocean-sci.net/13/61/2017/os-13-61-2017.pdf https://doaj.org/article/c41d356270bd49a6bc43382ebc5453ce en eng Copernicus Publications 1812-0784 1812-0792 doi:10.5194/os-13-61-2017 http://www.ocean-sci.net/13/61/2017/os-13-61-2017.pdf https://doaj.org/article/c41d356270bd49a6bc43382ebc5453ce undefined Ocean Science, Vol 13, Iss 1, Pp 61-75 (2017) geo envir Journal Article https://vocabularies.coar-repositories.org/resource_types/c_6501/ 2017 fttriple https://doi.org/10.5194/os-13-61-2017 2023-01-22T17:51:25Z In ice-covered regions it is challenging to determine constituent budgets – for heat and momentum, but also for biologically and climatically active gases like carbon dioxide and methane. The harsh environment and relative data scarcity make it difficult to characterize even the physical properties of the ocean surface. Here, we sought to evaluate if numerical model output helps us to better estimate the physical forcing that drives the air–sea gas exchange rate (k) in sea ice zones. We used the budget of radioactive 222Rn in the mixed layer to illustrate the effect that sea ice forcing has on gas budgets and air–sea gas exchange. Appropriate constraint of the 222Rn budget requires estimates of sea ice velocity, concentration, mixed-layer depth, and water velocities, as well as their evolution in time and space along the Lagrangian drift track of a mixed-layer water parcel. We used 36, 9 and 2 km horizontal resolution of regional Massachusetts Institute of Technology general circulation model (MITgcm) configuration with fine vertical spacing to evaluate the capability of the model to reproduce these parameters. We then compared the model results to existing field data including satellite, moorings and ice-tethered profilers. We found that mode sea ice coverage agrees with satellite-derived observation 88 to 98 % of the time when averaged over the Beaufort Gyre, and model sea ice speeds have 82 % correlation with observations. The model demonstrated the capacity to capture the broad trends in the mixed layer, although with a significant bias. Model water velocities showed only 29 % correlation with point-wise in situ data. This correlation remained low in all three model resolution simulations and we argued that is largely due to the quality of the input atmospheric forcing. Overall, we found that even the coarse-resolution model can make a modest contribution to gas exchange parameterization, by resolving the time variation of parameters that drive the 222Rn budget, including rate of mixed-layer change and sea ... Article in Journal/Newspaper Arctic Sea ice Unknown Arctic Ocean Science 13 1 61 75 |
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Open Polar |
| collection |
Unknown |
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fttriple |
| language |
English |
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geo envir |
| spellingShingle |
geo envir A. Bigdeli B. Loose A. T. Nguyen S. T. Cole Numerical investigation of the Arctic ice–ocean boundary layer and implications for air–sea gas fluxes |
| topic_facet |
geo envir |
| description |
In ice-covered regions it is challenging to determine constituent budgets – for heat and momentum, but also for biologically and climatically active gases like carbon dioxide and methane. The harsh environment and relative data scarcity make it difficult to characterize even the physical properties of the ocean surface. Here, we sought to evaluate if numerical model output helps us to better estimate the physical forcing that drives the air–sea gas exchange rate (k) in sea ice zones. We used the budget of radioactive 222Rn in the mixed layer to illustrate the effect that sea ice forcing has on gas budgets and air–sea gas exchange. Appropriate constraint of the 222Rn budget requires estimates of sea ice velocity, concentration, mixed-layer depth, and water velocities, as well as their evolution in time and space along the Lagrangian drift track of a mixed-layer water parcel. We used 36, 9 and 2 km horizontal resolution of regional Massachusetts Institute of Technology general circulation model (MITgcm) configuration with fine vertical spacing to evaluate the capability of the model to reproduce these parameters. We then compared the model results to existing field data including satellite, moorings and ice-tethered profilers. We found that mode sea ice coverage agrees with satellite-derived observation 88 to 98 % of the time when averaged over the Beaufort Gyre, and model sea ice speeds have 82 % correlation with observations. The model demonstrated the capacity to capture the broad trends in the mixed layer, although with a significant bias. Model water velocities showed only 29 % correlation with point-wise in situ data. This correlation remained low in all three model resolution simulations and we argued that is largely due to the quality of the input atmospheric forcing. Overall, we found that even the coarse-resolution model can make a modest contribution to gas exchange parameterization, by resolving the time variation of parameters that drive the 222Rn budget, including rate of mixed-layer change and sea ... |
| format |
Article in Journal/Newspaper |
| author |
A. Bigdeli B. Loose A. T. Nguyen S. T. Cole |
| author_facet |
A. Bigdeli B. Loose A. T. Nguyen S. T. Cole |
| author_sort |
A. Bigdeli |
| title |
Numerical investigation of the Arctic ice–ocean boundary layer and implications for air–sea gas fluxes |
| title_short |
Numerical investigation of the Arctic ice–ocean boundary layer and implications for air–sea gas fluxes |
| title_full |
Numerical investigation of the Arctic ice–ocean boundary layer and implications for air–sea gas fluxes |
| title_fullStr |
Numerical investigation of the Arctic ice–ocean boundary layer and implications for air–sea gas fluxes |
| title_full_unstemmed |
Numerical investigation of the Arctic ice–ocean boundary layer and implications for air–sea gas fluxes |
| title_sort |
numerical investigation of the arctic ice–ocean boundary layer and implications for air–sea gas fluxes |
| publisher |
Copernicus Publications |
| publishDate |
2017 |
| url |
https://doi.org/10.5194/os-13-61-2017 http://www.ocean-sci.net/13/61/2017/os-13-61-2017.pdf https://doaj.org/article/c41d356270bd49a6bc43382ebc5453ce |
| geographic |
Arctic |
| geographic_facet |
Arctic |
| genre |
Arctic Sea ice |
| genre_facet |
Arctic Sea ice |
| op_source |
Ocean Science, Vol 13, Iss 1, Pp 61-75 (2017) |
| op_relation |
1812-0784 1812-0792 doi:10.5194/os-13-61-2017 http://www.ocean-sci.net/13/61/2017/os-13-61-2017.pdf https://doaj.org/article/c41d356270bd49a6bc43382ebc5453ce |
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| op_doi |
https://doi.org/10.5194/os-13-61-2017 |
| container_title |
Ocean Science |
| container_volume |
13 |
| container_issue |
1 |
| container_start_page |
61 |
| op_container_end_page |
75 |
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1766347938961817600 |