Model-observation and reanalyses comparison at key locations for heat transport to the Arctic (D2.1)

Assessment of key lower latitude influences on the Arctic and their simulation Summary Blue-Action Work Package 2 (WP2) focuses on lower latitude drivers of Arctic change, with a focus on the influence of the Atlantic Ocean and atmosphere on the Arctic. In particular, warm water travels from the Atl...

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Main Authors: Moat, Ben, Herbaut, Christophe, Larsen, Karin Margretha, Hansen, Bogi, Sinha, Bablu, Sanchez-Franks, Alejandra, Houpert, Loic, Liu, Yang, Hazeleger, Wilco, Attema, Jisk, Yeager, Stephen, Small, Justin, Valdimarsson, Hedinn, Berx, Barbara, Cunningham, Stuart, Hallam, Samantha, Woodgate, Rebecca, Lee, Craig, Kwon, Young Oh, Flemming, Laura, Mercier, Herle, Jochumsen, Kerstin, Mecking, Jennifer, Holliday, Penny Holliday, Josey, Simon
Format: Text
Language:English
Published: Zenodo 2020
Subjects:
Arctic
Norwegian Sea
Canada
Greenland
Davis Strait
Denmark Strait
Greenland-Scotland Ridge
Iceland
North Atlantic
Sea ice
Online Access:https://dx.doi.org/10.5281/zenodo.3631100
https://zenodo.org/record/3631100
id ftdatacite:10.5281/zenodo.3631100
record_format openpolar
institution Open Polar
collection DataCite Metadata Store (German National Library of Science and Technology)
op_collection_id ftdatacite
language English
description Assessment of key lower latitude influences on the Arctic and their simulation Summary Blue-Action Work Package 2 (WP2) focuses on lower latitude drivers of Arctic change, with a focus on the influence of the Atlantic Ocean and atmosphere on the Arctic. In particular, warm water travels from the Atlantic, across the Greenland-Scotland ridge, through the Norwegian Sea towards the Arctic. A large proportion of the heat transported northwards by the ocean is released to the atmosphere and carried eastward towards Europe by the prevailing westerly winds. This is an important contribution to northwestern Europe's mild climate. The remaining heat travels north into the Arctic. Variations in the amount of heat transported into the Arctic will influence the long term climate of the Northern Hemisphere. Here we assess how well the state of the art coupled climate models estimate this northwards transport of heat in the ocean, and how the atmospheric heat transport varies with changes in the ocean heat transport. We seek to improve the ocean monitoring systems that are in place by introducing measurements from ocean gliders, Argo floats and satellites. These state of the art computer simulations are evaluated by comparison with key trans-Atlantic observations. In addition to the coupled models ‘ocean-only’ evaluations are made. In general the coupled model simulations have too much heat going into the Arctic region and the transports have too much variability. The models generally reproduce the variability of the Atlantic Meridional Ocean Circulation (AMOC) well. All models in this study have a too strong southwards transport of freshwater at 26°N in the North Atlantic, but the divergence between 26°N and Bering Straits is generally reproduced really well in all the models. Altimetry from satellites have been used to reconstruct the ocean circulation 26°N in the Atlantic, over the Greenland Scotland Ridge and alongside ship based observations along the GO-SHIP OVIDE Section. Although it is still a challenge to estimate the ocean circulation at 26°N without using the RAPID 26°N array, satellites can be used to reconstruct the longer term ocean signal. The OSNAP project measures the oceanic transport of heat across a section which stretches from Canada to the UK, via Greenland. The project has used ocean gliders to great success to measure the transport on the eastern side of the array. Every 10 days up to 4000 Argo floats measure temperature and salinity in the top 2000m of the ocean, away from ocean boundaries, and report back the measurements via satellite. These data are employed at 26°N in the Atlantic to enable the calculation of the heat and freshwater transports. As explained above, both ocean and atmosphere carry vast amounts of heat poleward in the Atlantic. In the long term average the Atlantic ocean releases large amounts of heat to the atmosphere between the subtropical and subpolar regions, heat which is then carried by the atmosphere to western Europe and the Arctic. On shorter timescales, interannual to decadal, the amounts of heat carried by ocean and atmosphere vary considerably. An important question is whether the total amount of heat transported, atmosphere plus ocean, remains roughly constant, whether significant amounts of heat are gained or lost from space and how the relative amount transported by the atmosphere and ocean change with time. This is an important distinction because the same amount of anomalous heat transport will have very different effects depending on whether it is transported by ocean or the atmosphere. For example the effects on Arctic sea ice will depend very much on whether the surface of the ice experiences anomalous warming by the atmosphere versus the base of the ice experiencing anomalous warming from the ocean. In Blue-Action we investigated the relationship between atmospheric and oceanic heat transports at key locations corresponding to the positions of observational arrays (RAPID at 26°N, OSNAP at ~55N, and the Denmark Strait, Iceland-Scotland Ridge and Davis Strait at ~67N) in a number of cutting edge high resolution coupled ocean-atmosphere simulations. We split the analysis into two different timescales, interannual to decadal (1-10 years) and multidecadal (greater than 10 years). In the 1-10 year case, the relationship between ocean and atmosphere transports is complex, but a robust result is that although there is little local correlation between oceanic and atmospheric heat transports, Correlations do occur at different latitudes. Thus increased oceanic heat transport at 26°N is accompanied by reduced heat transport at ~50N and a longitudinal shift in the location of atmospheric flow of heat into the Arctic. Conversely, on longer timescales, there appears to be a much stronger local compensation between oceanic and atmospheric heat transport i.e. Bjerknes compensation. : The Blue-Action project has received funding from the European Union's Horizon 2020 Research and Innovation Programme under Grant Agreement No 727852.
format Text
author Moat, Ben
Herbaut, Christophe
Larsen, Karin Margretha
Hansen, Bogi
Sinha, Bablu
Sanchez-Franks, Alejandra
Houpert, Loic
Liu, Yang
Hazeleger, Wilco
Attema, Jisk
Yeager, Stephen
Small, Justin
Valdimarsson, Hedinn
Berx, Barbara
Cunningham, Stuart
Houpert, Loic
Hallam, Samantha
Woodgate, Rebecca
Lee, Craig
Kwon, Young Oh
Flemming, Laura
Mercier, Herle
Jochumsen, Kerstin
Mecking, Jennifer
Holliday, Penny Holliday
Josey, Simon
spellingShingle Moat, Ben
Herbaut, Christophe
Larsen, Karin Margretha
Hansen, Bogi
Sinha, Bablu
Sanchez-Franks, Alejandra
Houpert, Loic
Liu, Yang
Hazeleger, Wilco
Attema, Jisk
Yeager, Stephen
Small, Justin
Valdimarsson, Hedinn
Berx, Barbara
Cunningham, Stuart
Houpert, Loic
Hallam, Samantha
Woodgate, Rebecca
Lee, Craig
Kwon, Young Oh
Flemming, Laura
Mercier, Herle
Jochumsen, Kerstin
Mecking, Jennifer
Holliday, Penny Holliday
Josey, Simon
Model-observation and reanalyses comparison at key locations for heat transport to the Arctic (D2.1)
author_facet Moat, Ben
Herbaut, Christophe
Larsen, Karin Margretha
Hansen, Bogi
Sinha, Bablu
Sanchez-Franks, Alejandra
Houpert, Loic
Liu, Yang
Hazeleger, Wilco
Attema, Jisk
Yeager, Stephen
Small, Justin
Valdimarsson, Hedinn
Berx, Barbara
Cunningham, Stuart
Houpert, Loic
Hallam, Samantha
Woodgate, Rebecca
Lee, Craig
Kwon, Young Oh
Flemming, Laura
Mercier, Herle
Jochumsen, Kerstin
Mecking, Jennifer
Holliday, Penny Holliday
Josey, Simon
author_sort Moat, Ben
title Model-observation and reanalyses comparison at key locations for heat transport to the Arctic (D2.1)
title_short Model-observation and reanalyses comparison at key locations for heat transport to the Arctic (D2.1)
title_full Model-observation and reanalyses comparison at key locations for heat transport to the Arctic (D2.1)
title_fullStr Model-observation and reanalyses comparison at key locations for heat transport to the Arctic (D2.1)
title_full_unstemmed Model-observation and reanalyses comparison at key locations for heat transport to the Arctic (D2.1)
title_sort model-observation and reanalyses comparison at key locations for heat transport to the arctic (d2.1)
publisher Zenodo
publishDate 2020
url https://dx.doi.org/10.5281/zenodo.3631100
https://zenodo.org/record/3631100
geographic Arctic
Norwegian Sea
Canada
Greenland
geographic_facet Arctic
Norwegian Sea
Canada
Greenland
genre Arctic
Davis Strait
Denmark Strait
Greenland
Greenland-Scotland Ridge
Iceland
North Atlantic
Norwegian Sea
Sea ice
genre_facet Arctic
Davis Strait
Denmark Strait
Greenland
Greenland-Scotland Ridge
Iceland
North Atlantic
Norwegian Sea
Sea ice
op_relation https://zenodo.org/communities/blue-actionh2020
https://dx.doi.org/10.5281/zenodo.3631099
https://zenodo.org/communities/blue-actionh2020
op_rights Open Access
Creative Commons Attribution 4.0 International
https://creativecommons.org/licenses/by/4.0/legalcode
cc-by-4.0
info:eu-repo/semantics/openAccess
op_rightsnorm CC-BY
op_doi https://doi.org/10.5281/zenodo.3631100
https://doi.org/10.5281/zenodo.3631099
_version_ 1766322260360036352
spelling ftdatacite:10.5281/zenodo.3631100 2023-05-15T14:51:12+02:00 Model-observation and reanalyses comparison at key locations for heat transport to the Arctic (D2.1) Moat, Ben Herbaut, Christophe Larsen, Karin Margretha Hansen, Bogi Sinha, Bablu Sanchez-Franks, Alejandra Houpert, Loic Liu, Yang Hazeleger, Wilco Attema, Jisk Yeager, Stephen Small, Justin Valdimarsson, Hedinn Berx, Barbara Cunningham, Stuart Houpert, Loic Hallam, Samantha Woodgate, Rebecca Lee, Craig Kwon, Young Oh Flemming, Laura Mercier, Herle Jochumsen, Kerstin Mecking, Jennifer Holliday, Penny Holliday Josey, Simon 2020 https://dx.doi.org/10.5281/zenodo.3631100 https://zenodo.org/record/3631100 en eng Zenodo https://zenodo.org/communities/blue-actionh2020 https://dx.doi.org/10.5281/zenodo.3631099 https://zenodo.org/communities/blue-actionh2020 Open Access Creative Commons Attribution 4.0 International https://creativecommons.org/licenses/by/4.0/legalcode cc-by-4.0 info:eu-repo/semantics/openAccess CC-BY Text Project deliverable article-journal ScholarlyArticle 2020 ftdatacite https://doi.org/10.5281/zenodo.3631100 https://doi.org/10.5281/zenodo.3631099 2021-11-05T12:55:41Z Assessment of key lower latitude influences on the Arctic and their simulation Summary Blue-Action Work Package 2 (WP2) focuses on lower latitude drivers of Arctic change, with a focus on the influence of the Atlantic Ocean and atmosphere on the Arctic. In particular, warm water travels from the Atlantic, across the Greenland-Scotland ridge, through the Norwegian Sea towards the Arctic. A large proportion of the heat transported northwards by the ocean is released to the atmosphere and carried eastward towards Europe by the prevailing westerly winds. This is an important contribution to northwestern Europe's mild climate. The remaining heat travels north into the Arctic. Variations in the amount of heat transported into the Arctic will influence the long term climate of the Northern Hemisphere. Here we assess how well the state of the art coupled climate models estimate this northwards transport of heat in the ocean, and how the atmospheric heat transport varies with changes in the ocean heat transport. We seek to improve the ocean monitoring systems that are in place by introducing measurements from ocean gliders, Argo floats and satellites. These state of the art computer simulations are evaluated by comparison with key trans-Atlantic observations. In addition to the coupled models ‘ocean-only’ evaluations are made. In general the coupled model simulations have too much heat going into the Arctic region and the transports have too much variability. The models generally reproduce the variability of the Atlantic Meridional Ocean Circulation (AMOC) well. All models in this study have a too strong southwards transport of freshwater at 26°N in the North Atlantic, but the divergence between 26°N and Bering Straits is generally reproduced really well in all the models. Altimetry from satellites have been used to reconstruct the ocean circulation 26°N in the Atlantic, over the Greenland Scotland Ridge and alongside ship based observations along the GO-SHIP OVIDE Section. Although it is still a challenge to estimate the ocean circulation at 26°N without using the RAPID 26°N array, satellites can be used to reconstruct the longer term ocean signal. The OSNAP project measures the oceanic transport of heat across a section which stretches from Canada to the UK, via Greenland. The project has used ocean gliders to great success to measure the transport on the eastern side of the array. Every 10 days up to 4000 Argo floats measure temperature and salinity in the top 2000m of the ocean, away from ocean boundaries, and report back the measurements via satellite. These data are employed at 26°N in the Atlantic to enable the calculation of the heat and freshwater transports. As explained above, both ocean and atmosphere carry vast amounts of heat poleward in the Atlantic. In the long term average the Atlantic ocean releases large amounts of heat to the atmosphere between the subtropical and subpolar regions, heat which is then carried by the atmosphere to western Europe and the Arctic. On shorter timescales, interannual to decadal, the amounts of heat carried by ocean and atmosphere vary considerably. An important question is whether the total amount of heat transported, atmosphere plus ocean, remains roughly constant, whether significant amounts of heat are gained or lost from space and how the relative amount transported by the atmosphere and ocean change with time. This is an important distinction because the same amount of anomalous heat transport will have very different effects depending on whether it is transported by ocean or the atmosphere. For example the effects on Arctic sea ice will depend very much on whether the surface of the ice experiences anomalous warming by the atmosphere versus the base of the ice experiencing anomalous warming from the ocean. In Blue-Action we investigated the relationship between atmospheric and oceanic heat transports at key locations corresponding to the positions of observational arrays (RAPID at 26°N, OSNAP at ~55N, and the Denmark Strait, Iceland-Scotland Ridge and Davis Strait at ~67N) in a number of cutting edge high resolution coupled ocean-atmosphere simulations. We split the analysis into two different timescales, interannual to decadal (1-10 years) and multidecadal (greater than 10 years). In the 1-10 year case, the relationship between ocean and atmosphere transports is complex, but a robust result is that although there is little local correlation between oceanic and atmospheric heat transports, Correlations do occur at different latitudes. Thus increased oceanic heat transport at 26°N is accompanied by reduced heat transport at ~50N and a longitudinal shift in the location of atmospheric flow of heat into the Arctic. Conversely, on longer timescales, there appears to be a much stronger local compensation between oceanic and atmospheric heat transport i.e. Bjerknes compensation. : The Blue-Action project has received funding from the European Union's Horizon 2020 Research and Innovation Programme under Grant Agreement No 727852. Text Arctic Davis Strait Denmark Strait Greenland Greenland-Scotland Ridge Iceland North Atlantic Norwegian Sea Sea ice DataCite Metadata Store (German National Library of Science and Technology) Arctic Norwegian Sea Canada Greenland

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