Heat loss from the Atlantic water layer in the northern Kara Sea: causes and consequences

A distinct, subsurface density front along the eastern St. Anna Trough in the northern Kara Sea is inferred from hydrographic observations in 1996 and 2008–2010. Direct velocity measurements show a persistent northward subsurface current (~ 20 cm s -1 ) along the St. Anna Trough eastern flank. This...

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Bibliographic Details
Published in:Ocean Science
Main Authors: Dmitrenko, I.A., Kirillov, S.A., Serra, N., Koldunov, N.V., Ivanov, V.V., Schauer, U., Polyakov, I.V., Barber, D., Janout, M., Lien, V.S., Makhotin, M., Aksenov, Y.
Format: Article in Journal/Newspaper
Language:English
Published: 2014
Subjects:
Arctic
Arctic Ocean
Kara Sea
St. Anna Trough
Nansen
Nansen Basin
Sea ice
Online Access:https://eprints.soton.ac.uk/363059/
https://eprints.soton.ac.uk/363059/1/os-10-719-2014.pdf
Description
Summary:A distinct, subsurface density front along the eastern St. Anna Trough in the northern Kara Sea is inferred from hydrographic observations in 1996 and 2008–2010. Direct velocity measurements show a persistent northward subsurface current (~ 20 cm s -1 ) along the St. Anna Trough eastern flank. This sheared flow, carrying the outflow from the Barents and Kara Seas to the Arctic Ocean, is also evident from shipboard observations as well as from geostrophic velocities and numerical model simulations. Although no clear evidence for the occurrence of shear instabilities could be obtained, we speculate that the enhanced vertical mixing along the St. Anna Trough eastern flank promoted by a vertical velocity shear favors the upward heat loss from the intermediate warm Atlantic water layer. The associated upward heat flux is inferred to 50–100 W m -2 using hydrographic data and model simulations. The zone of lowered sea ice thickness and concentration essentially marks the Atlantic water pathway in the St. Anna Trough and adjacent Nansen Basin continental margin from both sea-ice remote sensing observations and model simulations. In fact, the sea-ice shows a consistently delayed freeze-up onset during fall and a reduction in the sea-ice thickness during winter. This is consistent with our results on the enhanced Atlantic water heat loss along the Atlantic water pathway in the St. Anna Trough.

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