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Geostrophic Currents in the northern Nordic Seas - A Combined Dataset of Multi-Mission Satellite Altimetry and Ocean Modeling (data) (2019)

Müller, Felix L ; Dettmering, Denise ; Wekerle, Claudia ; [et al.]

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In: Technische Universität München | Supplement to: Müller, Felix L; Dettmering, Denise; Wekerle, Claudia; Schwatke, Christian; Passaro, Marcello; Bosch, Wolfgang; Seitz, Florian (2019): Geostrophic currents in the northern Nordic Seas from a combination of multi-mission satellite altimetry and ocean modeling. Earth System Science Data, 11(4), 1765-1781, https://doi.org/10.5194/essd-11-1765-2019

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Publication Date: 2023-10-28

Description: The data set contains combined Dynamic Ocean Topography (DOT) and geostrophic velocity components for the northern Nordic Seas between 1995 and 2012. It was produced in the frame of the DFG project NEG-OCEAN: Variations in ocean currents, sea-ice concentration, and sea surface temperature along the North-East coast of Greenland. The data is provided as Format 4 Classic NetCDF files on an unstructured triangular, Finite Element formulated grid. The data are characterized by daily sampling between 18.5.1995 and 3.4.2012 including data gaps and a consistent spatial resolution up to 1 km. More details can be found in the related User Manual. The dataset is based on Dynamic Ocean Topography (DOT) elevations from a combination of along-track satellite altimetry measurements with simulated differential water heights from the Finite Element Sea-ice Ocean Model Version 1.4 (FESOM, Wekerle et al., 2017, doi:10.1002/2017JC012974). The combination approach is described in detail in the related publication. The altimetry data include observations of the ESA satellites Envisat and ERS-2. The high-frequent altimetry range observations are retracked using the ALES+ algorithm (Passaro et al., 2018, doi:10.1016/j.rse.2018.02.074) and are classified into open-water/sea-ice conditions by applying a classification algorithm (Müller et al., 2017, doi:10.3390/rs9060551). All applied atmospheric and geophysical altimetry corrections are listed in Müller et al., 2019 (doi:10.5194/tc-13-611-2019).

Keywords: Dynamic Ocean Topography; File format; File name; File size; Geostrophic Currents; MULT; Multiple investigations; NEG-OCEAN; NordicSeas; North Atlantic; northern Nordic Seas; Ocean Modeling; Principal Component Analysis; Satellite altimetry; Uniform resource locator/link to file; Variations in ocean currents, sea ice concentration, and sea surface temperature along the North-East coast of Greenland

Type: Dataset

Format: text/tab-separated-values, 72 data points

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Intensification of the Atlantic Water Supply to the Arctic Ocean Through Fram Strait Induced by Arctic Sea Ice Decline (2021)

Wang, Qiang ; Wekerle, Claudia ; Wang, Xuezhu ; [et al.]

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Publication Date: 2021-07-24

Description: Substantial changes have occurred in the Arctic Ocean in the last decades. Not only sea ice has retreated significantly, but also the ocean at middepth showed a warming tendency. By using simulations we identified a mechanism that intensifies the upward trend in ocean heat supply to the Arctic Ocean through Fram Strait. The reduction in sea ice export through Fram Strait induced by Arctic sea ice decline increases the salinity in the Greenland Sea, which lowers the sea surface height and strengthens the cyclonic gyre circulation in the Nordic Seas. The Atlantic Water volume transport to the Nordic Seas and Arctic Ocean is consequently strengthened. This enhances the warming trend of the Arctic Atlantic Water layer, potentially contributing to the Arctic “Atlantification.” Our study suggests that the Nordic Seas can play the role of a switchyard to influence the heat budget of the Arctic Ocean.

Keywords: 551.46 ; Arctic Ocean ; Atlantic Water ; sea ice decline ; Nordic Seas ; Greenland Sea ; Atlantification

Language: English

Type: article

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Eddy Kinetic Energy in the Arctic Ocean From a Global Simulation With a 1-km Arctic (2021)

Wang, Qiang ; Koldunov, Nikolay V. ; Danilov, Sergey ; [et al.]

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Publication Date: 2021-10-12

Description: Simulating Arctic Ocean mesoscale eddies in ocean circulation models presents a great challenge because of their small size. This study employs an unstructured-mesh ocean-sea ice model to conduct a decadal-scale global simulation with a 1-km Arctic. It provides a basinwide overview of Arctic eddy energetics. Increasing model resolution from 4 to 1 km increases Arctic eddy kinetic energy (EKE) and total kinetic energy (TKE) by about 40% and 15%, respectively. EKE is the highest along main currents over topography slopes, where strong conversion from available potential energy to EKE takes place. It is high in halocline with a maximum typically centered in the depth range of 70–110 m, and in the Atlantic Water layer of the Eurasian Basin as well. The seasonal variability of EKE along the continental slopes of southern Canada and eastern Eurasian basins is similar, stronger in fall and weaker in spring.

Keywords: 551.46 ; Arctic Ocean ; mesoscale eddies ; eddy kinetic energy ; baroclinic instability

Language: English

Type: map

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Seasonal and Mesoscale Variability of the Two Atlantic Water Recirculation Pathways in Fram Strait (2021)

Hofmann, Zerlina ; von Appen, Wilken‐Jon ; Wekerle, Claudia

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Publication Date: 2021-09-29

Description: Atlantic Water (AW), which is transported northward by the West Spitsbergen Current (WSC), partly recirculates (i.e., turns westward) in Fram Strait. This determines how much heat and salt reaches the Arctic Ocean, and how much joins the East Greenland Current on its southward path. We describe the AW recirculation's location, seasonality, and mesoscale variability by analyzing the first observations from moored instruments at five latitudes in central Fram Strait, spanning a period from August 2016 to July 2018. We observe recirculation on the prime meridian at 78°50’N and 80°10’N, respectively south and north of the Molloy Hole, and no recirculation further south at 78°10’N and further north at 80°50’N. At a fifth mooring location northwest of the Molloy Hole at 79°30’N, we observe some influence of the two recirculation pathways. The southern recirculation is observed as a continuous westward flow that carries AW throughout the year, though it may be subject to broadening and narrowing. It is affected by eddies in spring, likely due to the seasonality of mesoscale instability in the WSC. The northern recirculation is observed solely as passing eddies on the prime meridian, which are strongest during late autumn and winter, and absent during summer. This seasonality is likely affected both by the conditions set by the WSC and by the sea ice. Open ocean eddies originating from the WSC interact with the sea ice edge when they subduct below the fresher, colder water.

Description: Plain Language Summary: West of Spitsbergen, the so‐called West Spitsbergen Current (WSC) carries relatively warm water towards the Arctic Ocean. Part of this water turns westward before it reaches the Arctic Ocean. Another current transports it back south along the Greenland shelf. We look at observations of temperature, salinity, and flow velocity from two years in the region. We find that the warm water flows westwards at two latitudes. At 78°50’N it flows westwards throughout the year, but is affected by eddies in the ocean during spring. These eddies also carry warm water westwards and likely originate from the WSC. At 80°10’N, the warm water passes only over periods of a few days, and only during late autumn, winter, and spring. That means that we do not observe the warm water flowing westwards at this latitude, but only eddies that carry it westwards. These eddies also originate from the WSC, and their properties likely change, when they meet the ice edge and have to push underneath.

Description: Key Points: We present the first multi‐year mooring‐based observations of the Atlantic Water recirculation at the prime meridian. At 78°50’N we observe a continuous westward flow, present throughout the year and most affected by eddies in spring. At 80°10′N we only observe passing eddies, which are strongest during late autumn and winter, and absent during summer.

Description: Deutsche Forschungsgemeinschaft http://dx.doi.org/10.13039/501100001659

Description: Helmholtz Infrastructure Initiative FRAM

Keywords: 551.46

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