Variability and Redistribution of Heat in the Atlantic Water Boundary Current North of Svalbard

Variability and Redistribution of Heat in the Atlantic Water Boundary Current North of Svalbard

We quantify Atlantic Water heat loss north of Svalbard using year‐long hydrographic and current records from three moorings deployed across the Svalbard Branch of the Atlantic Water boundary current in 2012–2013. The boundary current loses annually on average 16 W m−2 during the eastward propagation...

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Veröffentlicht in:Journal of geophysical research. Oceans 2018-09, Vol.123 (9), p.6373-6391
Hauptverfasser: Renner, A. H. H., Sundfjord, A., Janout, M. A., Ingvaldsen, R. B., Beszczynska‐Möller, A., Pickart, R. S., Pérez‐Hernández, M. D.
Format: Artikel
Sprache:eng
Schlagworte:
Advection
Air
Air-sea flux
Air-sea interaction
Annual variations
Arctic Ocean
Atlantic Water
Autumn
A‐TWAIN
boundary current
Boundary currents
Columns (structural)
Continental slope
Density stratification
Diurnal variations
Eddies
Ekman pumping
Geophysics
Halocline
Heat
Heat budget
Heat exchange
Heat flux
Heat loss
Heat transfer
Heat transport
Ice
Ice cover
Instruments
Meltwater
Mesoscale eddies
Mooring
Nansen Basin
Ocean circulation
Oceans
Sea ice
Seasonal variations
Semidiurnal tides
Slopes
Stability
Stratification
Temperature (air-sea)
Tidal energy
Tides
Upwelling
Water boundary
Water column
Wind
Winter
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container_end_page 6391
container_issue 9
container_start_page 6373
container_title Journal of geophysical research. Oceans
container_volume 123
creator Renner, A. H. H.
Sundfjord, A.
Janout, M. A.
Ingvaldsen, R. B.
Beszczynska‐Möller, A.
Pickart, R. S.
Pérez‐Hernández, M. D.
description We quantify Atlantic Water heat loss north of Svalbard using year‐long hydrographic and current records from three moorings deployed across the Svalbard Branch of the Atlantic Water boundary current in 2012–2013. The boundary current loses annually on average 16 W m−2 during the eastward propagation along the upper continental slope. The largest vertical fluxes of >100 W m−2 occur episodically in autumn and early winter. Episodes of sea ice imported from the north in November 2012 and February 2013 coincided with large ocean‐to‐ice heat fluxes, which effectively melted the ice and sustained open water conditions in the middle of the Arctic winter. Between March and early July 2013, a persistent ice cover‐modulated air‐sea fluxes. Melting sea ice at the start of the winter initiates a cold, up to 100‐m‐deep halocline separating the ice cover from the warm Atlantic Water. Semidiurnal tides dominate the energy over the upper part of the slope. The vertical tidal structure depends on stratification and varies seasonally, with the potential to contribute to vertical fluxes with shear‐driven mixing. Further processes impacting the heat budget include lateral heat loss due to mesoscale eddies, and modest and negligible contributions of Ekman pumping and shelf break upwelling, respectively. The continental slope north of Svalbard is a key example regarding the role of ocean heat for the sea ice cover. Our study underlines the complexity of the ocean's heat budget that is sensitive to the balance between oceanic heat advection, vertical fluxes, air‐sea interaction, and the sea ice cover. Plain Language Summary The Atlantic Water boundary current carries heat into the Arctic Ocean as it flows through Fram Strait and along the continental slope north of Svalbard. Using observations from bottom‐mounted instruments, we investigated different processes leading to heat loss from the Atlantic Water layer in the region north of Svalbard. Most of the changes recorded over the course of 1 year from September 2012 to September 2013 at 81.5°N, 31°E are driven by changes further upstream and by air‐sea heat exchange. However, significant local heat loss can be caused by mixing due to wind or tides. Seasonal differences are large and predominantly caused by absence or presence of sea ice (autumn/early winter versus spring/early summer), influence of melt water and wind on the stability of the water column, and a seasonally changing light regime. Key Points We present year‐long r
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H. H. ; Sundfjord, A. ; Janout, M. A. ; Ingvaldsen, R. B. ; Beszczynska‐Möller, A. ; Pickart, R. S. ; Pérez‐Hernández, M. D.</creator><creatorcontrib>Renner, A. H. H. ; Sundfjord, A. ; Janout, M. A. ; Ingvaldsen, R. B. ; Beszczynska‐Möller, A. ; Pickart, R. S. ; Pérez‐Hernández, M. D.</creatorcontrib><description>We quantify Atlantic Water heat loss north of Svalbard using year‐long hydrographic and current records from three moorings deployed across the Svalbard Branch of the Atlantic Water boundary current in 2012–2013. The boundary current loses annually on average 16 W m−2 during the eastward propagation along the upper continental slope. The largest vertical fluxes of &gt;100 W m−2 occur episodically in autumn and early winter. Episodes of sea ice imported from the north in November 2012 and February 2013 coincided with large ocean‐to‐ice heat fluxes, which effectively melted the ice and sustained open water conditions in the middle of the Arctic winter. Between March and early July 2013, a persistent ice cover‐modulated air‐sea fluxes. Melting sea ice at the start of the winter initiates a cold, up to 100‐m‐deep halocline separating the ice cover from the warm Atlantic Water. Semidiurnal tides dominate the energy over the upper part of the slope. The vertical tidal structure depends on stratification and varies seasonally, with the potential to contribute to vertical fluxes with shear‐driven mixing. Further processes impacting the heat budget include lateral heat loss due to mesoscale eddies, and modest and negligible contributions of Ekman pumping and shelf break upwelling, respectively. The continental slope north of Svalbard is a key example regarding the role of ocean heat for the sea ice cover. Our study underlines the complexity of the ocean's heat budget that is sensitive to the balance between oceanic heat advection, vertical fluxes, air‐sea interaction, and the sea ice cover. Plain Language Summary The Atlantic Water boundary current carries heat into the Arctic Ocean as it flows through Fram Strait and along the continental slope north of Svalbard. Using observations from bottom‐mounted instruments, we investigated different processes leading to heat loss from the Atlantic Water layer in the region north of Svalbard. Most of the changes recorded over the course of 1 year from September 2012 to September 2013 at 81.5°N, 31°E are driven by changes further upstream and by air‐sea heat exchange. However, significant local heat loss can be caused by mixing due to wind or tides. Seasonal differences are large and predominantly caused by absence or presence of sea ice (autumn/early winter versus spring/early summer), influence of melt water and wind on the stability of the water column, and a seasonally changing light regime. Key Points We present year‐long records of hydrography and currents of the Atlantic Water boundary current north of Svalbard Upper ocean heat loss is 16 W m−2 annually with episodic heat loss of &gt;100 W m−2 in autumn and winter AW inflow drives 80% of heat content variability, with wind‐induced mixing and tidal mixing as the other main factors</description><identifier>ISSN: 2169-9275</identifier><identifier>EISSN: 2169-9291</identifier><identifier>DOI: 10.1029/2018JC013814</identifier><language>eng</language><publisher>Washington: Blackwell Publishing Ltd</publisher><subject>Advection ; Air ; Air-sea flux ; Air-sea interaction ; Annual variations ; Arctic Ocean ; Atlantic Water ; Autumn ; A‐TWAIN ; boundary current ; Boundary currents ; Columns (structural) ; Continental slope ; Density stratification ; Diurnal variations ; Eddies ; Ekman pumping ; Geophysics ; Halocline ; Heat ; Heat budget ; Heat exchange ; Heat flux ; Heat loss ; Heat transfer ; Heat transport ; Ice ; Ice cover ; Instruments ; Meltwater ; Mesoscale eddies ; Mooring ; Nansen Basin ; Ocean circulation ; Oceans ; Sea ice ; Seasonal variations ; Semidiurnal tides ; Slopes ; Stability ; Stratification ; Temperature (air-sea) ; Tidal energy ; Tides ; Upwelling ; Water boundary ; Water column ; Wind ; Winter</subject><ispartof>Journal of geophysical research. Oceans, 2018-09, Vol.123 (9), p.6373-6391</ispartof><rights>2018. The Authors.</rights><rights>2018. American Geophysical Union. All rights reserved.</rights><lds50>peer_reviewed</lds50><oa>free_for_read</oa><woscitedreferencessubscribed>false</woscitedreferencessubscribed><citedby>FETCH-LOGICAL-a4114-4ca3edbd11d80ac369da96632b16f4f779554a55363bf8e52c9fe15c0c27d1153</citedby><cites>FETCH-LOGICAL-a4114-4ca3edbd11d80ac369da96632b16f4f779554a55363bf8e52c9fe15c0c27d1153</cites><orcidid>0000-0002-3921-1038 ; 0000-0001-7293-9584 ; 0000-0002-6913-3368 ; 0000-0002-8108-6306 ; 0000-0002-9997-6366 ; 0000-0002-7826-911X ; 0000-0003-4908-2855</orcidid></display><links><openurl>$$Topenurl_article</openurl><openurlfulltext>$$Topenurlfull_article</openurlfulltext><thumbnail>$$Tsyndetics_thumb_exl</thumbnail><linktopdf>$$Uhttps://onlinelibrary.wiley.com/doi/pdf/10.1029%2F2018JC013814$$EPDF$$P50$$Gwiley$$Hfree_for_read</linktopdf><linktohtml>$$Uhttps://onlinelibrary.wiley.com/doi/full/10.1029%2F2018JC013814$$EHTML$$P50$$Gwiley$$Hfree_for_read</linktohtml><link.rule.ids>315,782,786,1419,1435,27933,27934,45583,45584,46418,46842</link.rule.ids></links><search><creatorcontrib>Renner, A. H. H.</creatorcontrib><creatorcontrib>Sundfjord, A.</creatorcontrib><creatorcontrib>Janout, M. A.</creatorcontrib><creatorcontrib>Ingvaldsen, R. B.</creatorcontrib><creatorcontrib>Beszczynska‐Möller, A.</creatorcontrib><creatorcontrib>Pickart, R. S.</creatorcontrib><creatorcontrib>Pérez‐Hernández, M. D.</creatorcontrib><title>Variability and Redistribution of Heat in the Atlantic Water Boundary Current North of Svalbard</title><title>Journal of geophysical research. Oceans</title><description>We quantify Atlantic Water heat loss north of Svalbard using year‐long hydrographic and current records from three moorings deployed across the Svalbard Branch of the Atlantic Water boundary current in 2012–2013. The boundary current loses annually on average 16 W m−2 during the eastward propagation along the upper continental slope. The largest vertical fluxes of &gt;100 W m−2 occur episodically in autumn and early winter. Episodes of sea ice imported from the north in November 2012 and February 2013 coincided with large ocean‐to‐ice heat fluxes, which effectively melted the ice and sustained open water conditions in the middle of the Arctic winter. Between March and early July 2013, a persistent ice cover‐modulated air‐sea fluxes. Melting sea ice at the start of the winter initiates a cold, up to 100‐m‐deep halocline separating the ice cover from the warm Atlantic Water. Semidiurnal tides dominate the energy over the upper part of the slope. The vertical tidal structure depends on stratification and varies seasonally, with the potential to contribute to vertical fluxes with shear‐driven mixing. Further processes impacting the heat budget include lateral heat loss due to mesoscale eddies, and modest and negligible contributions of Ekman pumping and shelf break upwelling, respectively. The continental slope north of Svalbard is a key example regarding the role of ocean heat for the sea ice cover. Our study underlines the complexity of the ocean's heat budget that is sensitive to the balance between oceanic heat advection, vertical fluxes, air‐sea interaction, and the sea ice cover. Plain Language Summary The Atlantic Water boundary current carries heat into the Arctic Ocean as it flows through Fram Strait and along the continental slope north of Svalbard. Using observations from bottom‐mounted instruments, we investigated different processes leading to heat loss from the Atlantic Water layer in the region north of Svalbard. Most of the changes recorded over the course of 1 year from September 2012 to September 2013 at 81.5°N, 31°E are driven by changes further upstream and by air‐sea heat exchange. However, significant local heat loss can be caused by mixing due to wind or tides. Seasonal differences are large and predominantly caused by absence or presence of sea ice (autumn/early winter versus spring/early summer), influence of melt water and wind on the stability of the water column, and a seasonally changing light regime. Key Points We present year‐long records of hydrography and currents of the Atlantic Water boundary current north of Svalbard Upper ocean heat loss is 16 W m−2 annually with episodic heat loss of &gt;100 W m−2 in autumn and winter AW inflow drives 80% of heat content variability, with wind‐induced mixing and tidal mixing as the other main factors</description><subject>Advection</subject><subject>Air</subject><subject>Air-sea flux</subject><subject>Air-sea interaction</subject><subject>Annual variations</subject><subject>Arctic Ocean</subject><subject>Atlantic Water</subject><subject>Autumn</subject><subject>A‐TWAIN</subject><subject>boundary current</subject><subject>Boundary currents</subject><subject>Columns (structural)</subject><subject>Continental slope</subject><subject>Density stratification</subject><subject>Diurnal variations</subject><subject>Eddies</subject><subject>Ekman pumping</subject><subject>Geophysics</subject><subject>Halocline</subject><subject>Heat</subject><subject>Heat budget</subject><subject>Heat exchange</subject><subject>Heat flux</subject><subject>Heat loss</subject><subject>Heat transfer</subject><subject>Heat transport</subject><subject>Ice</subject><subject>Ice cover</subject><subject>Instruments</subject><subject>Meltwater</subject><subject>Mesoscale eddies</subject><subject>Mooring</subject><subject>Nansen Basin</subject><subject>Ocean circulation</subject><subject>Oceans</subject><subject>Sea ice</subject><subject>Seasonal variations</subject><subject>Semidiurnal tides</subject><subject>Slopes</subject><subject>Stability</subject><subject>Stratification</subject><subject>Temperature (air-sea)</subject><subject>Tidal energy</subject><subject>Tides</subject><subject>Upwelling</subject><subject>Water boundary</subject><subject>Water column</subject><subject>Wind</subject><subject>Winter</subject><issn>2169-9275</issn><issn>2169-9291</issn><fulltext>true</fulltext><rsrctype>article</rsrctype><creationdate>2018</creationdate><recordtype>article</recordtype><sourceid>24P</sourceid><sourceid>WIN</sourceid><recordid>eNp9kEtPwzAQhC0EElXpjR9giSsBr1-JjyWClqoCqbyOlhM7qquQFMcB9d-TqghxYi-7h29mtIPQOZArIFRdUwLZIifAMuBHaERBqkRRBce_dypO0aTrNmSYDDLO1QjpVxO8KXzt4w6bxuKVs76LwRd99G2D2wrPnYnYNziuHZ7G2jTRl_jNRBfwTds31oQdzvsQXBPxQxviei96-jR1YYI9QyeVqTs3-dlj9HJ3-5zPk-Xj7D6fLhPDAXjCS8OcLSyAzYgpmVTWKCkZLUBWvEpTJQQ3QjDJiipzgpaqciBKUtJ0EAk2RhcH321oP3rXRb1p-9AMkZoCJZJIpvhAXR6oMrRdF1ylt8G_Dw9oIHrfov7b4oCzA_7la7f7l9WL2SqnjKScfQOgi3JW</recordid><startdate>201809</startdate><enddate>201809</enddate><creator>Renner, A. 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H. H.</creatorcontrib><creatorcontrib>Sundfjord, A.</creatorcontrib><creatorcontrib>Janout, M. A.</creatorcontrib><creatorcontrib>Ingvaldsen, R. B.</creatorcontrib><creatorcontrib>Beszczynska‐Möller, A.</creatorcontrib><creatorcontrib>Pickart, R. S.</creatorcontrib><creatorcontrib>Pérez‐Hernández, M. D.</creatorcontrib><collection>Wiley Online Library (Open Access Collection)</collection><collection>Wiley Online Library (Open Access Collection)</collection><collection>CrossRef</collection><collection>Meteorological &amp; Geoastrophysical Abstracts</collection><collection>Oceanic Abstracts</collection><collection>ASFA: Aquatic Sciences and Fisheries Abstracts</collection><collection>Aquatic Science &amp; Fisheries Abstracts (ASFA) 2: Ocean Technology, Policy &amp; Non-Living Resources</collection><collection>Meteorological &amp; Geoastrophysical Abstracts - Academic</collection><collection>Aquatic Science &amp; Fisheries Abstracts (ASFA) Professional</collection><jtitle>Journal of geophysical research. Oceans</jtitle></facets><delivery><delcategory>Remote Search Resource</delcategory><fulltext>fulltext</fulltext></delivery><addata><au>Renner, A. H. H.</au><au>Sundfjord, A.</au><au>Janout, M. A.</au><au>Ingvaldsen, R. B.</au><au>Beszczynska‐Möller, A.</au><au>Pickart, R. S.</au><au>Pérez‐Hernández, M. D.</au><format>journal</format><genre>article</genre><ristype>JOUR</ristype><atitle>Variability and Redistribution of Heat in the Atlantic Water Boundary Current North of Svalbard</atitle><jtitle>Journal of geophysical research. Oceans</jtitle><date>2018-09</date><risdate>2018</risdate><volume>123</volume><issue>9</issue><spage>6373</spage><epage>6391</epage><pages>6373-6391</pages><issn>2169-9275</issn><eissn>2169-9291</eissn><abstract>We quantify Atlantic Water heat loss north of Svalbard using year‐long hydrographic and current records from three moorings deployed across the Svalbard Branch of the Atlantic Water boundary current in 2012–2013. The boundary current loses annually on average 16 W m−2 during the eastward propagation along the upper continental slope. The largest vertical fluxes of &gt;100 W m−2 occur episodically in autumn and early winter. Episodes of sea ice imported from the north in November 2012 and February 2013 coincided with large ocean‐to‐ice heat fluxes, which effectively melted the ice and sustained open water conditions in the middle of the Arctic winter. Between March and early July 2013, a persistent ice cover‐modulated air‐sea fluxes. Melting sea ice at the start of the winter initiates a cold, up to 100‐m‐deep halocline separating the ice cover from the warm Atlantic Water. Semidiurnal tides dominate the energy over the upper part of the slope. The vertical tidal structure depends on stratification and varies seasonally, with the potential to contribute to vertical fluxes with shear‐driven mixing. Further processes impacting the heat budget include lateral heat loss due to mesoscale eddies, and modest and negligible contributions of Ekman pumping and shelf break upwelling, respectively. The continental slope north of Svalbard is a key example regarding the role of ocean heat for the sea ice cover. Our study underlines the complexity of the ocean's heat budget that is sensitive to the balance between oceanic heat advection, vertical fluxes, air‐sea interaction, and the sea ice cover. Plain Language Summary The Atlantic Water boundary current carries heat into the Arctic Ocean as it flows through Fram Strait and along the continental slope north of Svalbard. Using observations from bottom‐mounted instruments, we investigated different processes leading to heat loss from the Atlantic Water layer in the region north of Svalbard. Most of the changes recorded over the course of 1 year from September 2012 to September 2013 at 81.5°N, 31°E are driven by changes further upstream and by air‐sea heat exchange. However, significant local heat loss can be caused by mixing due to wind or tides. Seasonal differences are large and predominantly caused by absence or presence of sea ice (autumn/early winter versus spring/early summer), influence of melt water and wind on the stability of the water column, and a seasonally changing light regime. Key Points We present year‐long records of hydrography and currents of the Atlantic Water boundary current north of Svalbard Upper ocean heat loss is 16 W m−2 annually with episodic heat loss of &gt;100 W m−2 in autumn and winter AW inflow drives 80% of heat content variability, with wind‐induced mixing and tidal mixing as the other main factors</abstract><cop>Washington</cop><pub>Blackwell Publishing Ltd</pub><doi>10.1029/2018JC013814</doi><tpages>19</tpages><orcidid>https://orcid.org/0000-0002-3921-1038</orcidid><orcidid>https://orcid.org/0000-0001-7293-9584</orcidid><orcidid>https://orcid.org/0000-0002-6913-3368</orcidid><orcidid>https://orcid.org/0000-0002-8108-6306</orcidid><orcidid>https://orcid.org/0000-0002-9997-6366</orcidid><orcidid>https://orcid.org/0000-0002-7826-911X</orcidid><orcidid>https://orcid.org/0000-0003-4908-2855</orcidid><oa>free_for_read</oa></addata></record>
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subjects Advection
Air
Air-sea flux
Air-sea interaction
Annual variations
Arctic Ocean
Atlantic Water
Autumn
A‐TWAIN
boundary current
Boundary currents
Columns (structural)
Continental slope
Density stratification
Diurnal variations
Eddies
Ekman pumping
Geophysics
Halocline
Heat
Heat budget
Heat exchange
Heat flux
Heat loss
Heat transfer
Heat transport
Ice
Ice cover
Instruments
Meltwater
Mesoscale eddies
Mooring
Nansen Basin
Ocean circulation
Oceans
Sea ice
Seasonal variations
Semidiurnal tides
Slopes
Stability
Stratification
Temperature (air-sea)
Tidal energy
Tides
Upwelling
Water boundary
Water column
Wind
Winter
title Variability and Redistribution of Heat in the Atlantic Water Boundary Current North of Svalbard
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