Three Forcing Mechanisms of Freshwater Transport in Fram Strait

Fram Strait is one of the main gateways for fresh water leaving the Arctic Ocean toward the deep‐water formation regions of the North Atlantic. Monitoring transport through Fram Strait is important to quantify the impact of Arctic amplification on the hydrography in lower latitudes. We update existi...

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Bibliographic Details
Published in:Journal of geophysical research. Oceans 2024-08, Vol.129 (8), p.n/a
Main Authors: Karpouzoglou, T., De Steur, L., Smedsrud, L. H., Karcher, M., Sumata, H.
Format: Article
Language:English
Subjects:
Anomalies
Arctic ocean
Arctic Oscillation
Convergence
Correlation
forcing mechanisms
Fram strait
Fresh water
Freshwater
Hydrography
Inland water environment
Interannual variability
Latitude
Meridional overturning circulation
Mooring
North Pole
Oceanic oscillations
Oceans
Preconditioning
Remote sensing
Salinity
Straits
Stratification
Time series
Variability
Volume transport
Water stratification
Wind
Winds
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Summary:Fram Strait is one of the main gateways for fresh water leaving the Arctic Ocean toward the deep‐water formation regions of the North Atlantic. Monitoring transport through Fram Strait is important to quantify the impact of Arctic amplification on the hydrography in lower latitudes. We update existing time series from the moorings in the western Fram Strait and investigate the monthly and interannual variability of the liquid freshwater transport (FWT, reference salinity 34.9), volume transport and freshwater content between 2003 and 2020. We examine composites and correlations of sea‐level pressure (SLP) reanalysis, and remote‐sensing dynamic‐ocean topography (DOT) in the Arctic Ocean. We identify two remote forcing mechanisms of FWT: (a) North Pole convergence freshens the region north of Fram Strait 13–24 months before high FWT events. (b) Beaufort Gyre weakening allows spreading of fresh water to the margins of the Arctic Basin zero to 9 months before high FWT events. In addition a third mechanism occurs locally, (b) Fram Strait northerly winds confine freshwater to the Greenland shelf and drive stronger southward FWT. Additionally, we find a decreasing trend in the total volume transport, concurrent with weakening northerly winds and reducing north‐south DOT gradient across the strait. We also examined correlations between the Fram Strait time series and the Arctic Oscillation and Arctic Ocean Oscillation. Both are found to correlate positively with the total volume transport, while the Arctic Oscillation correlates negatively with FWT with 1‐year lag. Plain Language Summary The East Greenland Current brings fresh water from the central Arctic Ocean to lower latitudes. The exported fresh water affects stratification, and can contribute to variations of the global meridional overturning circulation. In Fram Strait, between Greenland and Svalbard, the properties of this current have been systematically monitored using moored instruments. We present updated time series of freshwater transport from the moorings in the Fram Strait, and analyze their variability between 2003 and 2020. We identify three mechanisms that contribute to high freshwater transport in the Strait. (a) 13–24 months before, clockwise wind anomalies in the Eurasian Arctic drive converging current anomalies and freshen the area preconditioning fresh outflow events. (b) 0–9 months before, anticlockwise wind anomalies in the Canadian Arctic drive diverging current anomalies directing fres
ISSN:2169-9275
2169-9291
DOI:10.1029/2024JC020930