Structure and drivers of ocean mixing north of Svalbard in summer and fall 2018
The Arctic Ocean is a major sink for heat and salt for the global ocean. Ocean mixing contributes to this sink by mixing the Atlantic- and Pacific-origin waters with surrounding waters. We investigate the drivers of ocean mixing north of Svalbard, in the Atlantic sector of the Arctic, based on obser...
| Published in: | Ocean Science |
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| Format: | Article in Journal/Newspaper |
| Language: | English |
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Copernicus Publications
2021
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| Online Access: | https://doi.org/10.5194/os-17-365-2021 https://os.copernicus.org/articles/17/365/2021/os-17-365-2021.pdf https://doaj.org/article/e6b99d4821bf4936b49ad871c175c74f |
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fttriple:oai:gotriple.eu:oai:doaj.org/article:e6b99d4821bf4936b49ad871c175c74f 2023-05-15T14:58:10+02:00 Structure and drivers of ocean mixing north of Svalbard in summer and fall 2018 Z. Koenig E. H. Kolås I. Fer 2021-02-01 https://doi.org/10.5194/os-17-365-2021 https://os.copernicus.org/articles/17/365/2021/os-17-365-2021.pdf https://doaj.org/article/e6b99d4821bf4936b49ad871c175c74f en eng Copernicus Publications doi:10.5194/os-17-365-2021 1812-0784 1812-0792 https://os.copernicus.org/articles/17/365/2021/os-17-365-2021.pdf https://doaj.org/article/e6b99d4821bf4936b49ad871c175c74f undefined Ocean Science, Vol 17, Pp 365-381 (2021) envir geo Journal Article https://vocabularies.coar-repositories.org/resource_types/c_6501/ 2021 fttriple https://doi.org/10.5194/os-17-365-2021 2023-01-22T19:24:37Z The Arctic Ocean is a major sink for heat and salt for the global ocean. Ocean mixing contributes to this sink by mixing the Atlantic- and Pacific-origin waters with surrounding waters. We investigate the drivers of ocean mixing north of Svalbard, in the Atlantic sector of the Arctic, based on observations collected during two research cruises in summer and fall 2018. Estimates of vertical turbulent heat flux from the Atlantic Water layer up to the mixed layer reach 30 W m−2 in the core of the boundary current, and average to 8 W m−2, accounting for ∼1 % of the total heat loss of the Atlantic layer in the region. In the mixed layer, there is a nonlinear relation between the layer-integrated dissipation and wind energy input; convection was active at a few stations and was responsible for enhanced turbulence compared to what was expected from the wind stress alone. Summer melting of sea ice reduces the temperature, salinity and depth of the mixed layer and increases salt and buoyancy fluxes at the base of the mixed layer. Deeper in the water column and near the seabed, tidal forcing is a major source of turbulence: diapycnal diffusivity in the bottom 250 m of the water column is enhanced during strong tidal currents, reaching on average 10−3 m2 s−1. The average profile of diffusivity decays with distance from the seabed with an e-folding scale of 22 m compared to 18 m in conditions with weaker tidal currents. A nonlinear relation is inferred between the depth-integrated dissipation in the bottom 250 m of the water column and the tidally driven bottom drag and is used to estimate the bottom dissipation along the continental slope of the Eurasian Basin. Computation of an inverse Froude number suggests that nonlinear internal waves forced by the diurnal tidal currents (K1 constituent) can develop north of Svalbard and in the Laptev and Kara seas, with the potential to mix the entire water column vertically. Understanding the drivers of turbulence and the nonlinear pathways for the energy to turbulence in the Arctic ... Article in Journal/Newspaper Arctic Arctic Ocean laptev Sea ice Svalbard Unknown Arctic Arctic Ocean Pacific Svalbard Ocean Science 17 1 365 381 |
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English |
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envir geo |
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envir geo Z. Koenig E. H. Kolås I. Fer Structure and drivers of ocean mixing north of Svalbard in summer and fall 2018 |
| topic_facet |
envir geo |
| description |
The Arctic Ocean is a major sink for heat and salt for the global ocean. Ocean mixing contributes to this sink by mixing the Atlantic- and Pacific-origin waters with surrounding waters. We investigate the drivers of ocean mixing north of Svalbard, in the Atlantic sector of the Arctic, based on observations collected during two research cruises in summer and fall 2018. Estimates of vertical turbulent heat flux from the Atlantic Water layer up to the mixed layer reach 30 W m−2 in the core of the boundary current, and average to 8 W m−2, accounting for ∼1 % of the total heat loss of the Atlantic layer in the region. In the mixed layer, there is a nonlinear relation between the layer-integrated dissipation and wind energy input; convection was active at a few stations and was responsible for enhanced turbulence compared to what was expected from the wind stress alone. Summer melting of sea ice reduces the temperature, salinity and depth of the mixed layer and increases salt and buoyancy fluxes at the base of the mixed layer. Deeper in the water column and near the seabed, tidal forcing is a major source of turbulence: diapycnal diffusivity in the bottom 250 m of the water column is enhanced during strong tidal currents, reaching on average 10−3 m2 s−1. The average profile of diffusivity decays with distance from the seabed with an e-folding scale of 22 m compared to 18 m in conditions with weaker tidal currents. A nonlinear relation is inferred between the depth-integrated dissipation in the bottom 250 m of the water column and the tidally driven bottom drag and is used to estimate the bottom dissipation along the continental slope of the Eurasian Basin. Computation of an inverse Froude number suggests that nonlinear internal waves forced by the diurnal tidal currents (K1 constituent) can develop north of Svalbard and in the Laptev and Kara seas, with the potential to mix the entire water column vertically. Understanding the drivers of turbulence and the nonlinear pathways for the energy to turbulence in the Arctic ... |
| format |
Article in Journal/Newspaper |
| author |
Z. Koenig E. H. Kolås I. Fer |
| author_facet |
Z. Koenig E. H. Kolås I. Fer |
| author_sort |
Z. Koenig |
| title |
Structure and drivers of ocean mixing north of Svalbard in summer and fall 2018 |
| title_short |
Structure and drivers of ocean mixing north of Svalbard in summer and fall 2018 |
| title_full |
Structure and drivers of ocean mixing north of Svalbard in summer and fall 2018 |
| title_fullStr |
Structure and drivers of ocean mixing north of Svalbard in summer and fall 2018 |
| title_full_unstemmed |
Structure and drivers of ocean mixing north of Svalbard in summer and fall 2018 |
| title_sort |
structure and drivers of ocean mixing north of svalbard in summer and fall 2018 |
| publisher |
Copernicus Publications |
| publishDate |
2021 |
| url |
https://doi.org/10.5194/os-17-365-2021 https://os.copernicus.org/articles/17/365/2021/os-17-365-2021.pdf https://doaj.org/article/e6b99d4821bf4936b49ad871c175c74f |
| geographic |
Arctic Arctic Ocean Pacific Svalbard |
| geographic_facet |
Arctic Arctic Ocean Pacific Svalbard |
| genre |
Arctic Arctic Ocean laptev Sea ice Svalbard |
| genre_facet |
Arctic Arctic Ocean laptev Sea ice Svalbard |
| op_source |
Ocean Science, Vol 17, Pp 365-381 (2021) |
| op_relation |
doi:10.5194/os-17-365-2021 1812-0784 1812-0792 https://os.copernicus.org/articles/17/365/2021/os-17-365-2021.pdf https://doaj.org/article/e6b99d4821bf4936b49ad871c175c74f |
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https://doi.org/10.5194/os-17-365-2021 |
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Ocean Science |
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17 |
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1 |
| container_start_page |
365 |
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381 |
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