Decreasing intensity of open-ocean convection in the Greenland and Iceland seas

The air–sea transfer of heat and fresh water plays a critical role in the global climate system1. This is particularly true for the Greenland and Iceland seas, where these fluxes drive ocean convection that contributes to Denmark Strait overflow water, the densest component of the lower limb of the...

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Bibliographic Details
Published in:Nature Climate Change
Main Authors: G. W. K. Moore, K. Våge, R. S. Pickart, I. A. Renfrew
Format: Article in Journal/Newspaper
Language:unknown
Published: 2015
Subjects:
Greenland
Denmark Strait
Greenland Sea
Greenland-Scotland Ridge
Iceland
Labrador Sea
Nordic Seas
North Atlantic
North Atlantic oscillation
Sea ice
Online Access:https://zenodo.org/record/44967
https://doi.org/10.1038/nclimate2688
Description
Summary:The air–sea transfer of heat and fresh water plays a critical role in the global climate system1. This is particularly true for the Greenland and Iceland seas, where these fluxes drive ocean convection that contributes to Denmark Strait overflow water, the densest component of the lower limb of the Atlantic Meridional Overturning Circulation (AMOC; ref. 2). Here we show that the wintertime retreat of sea ice in the region, combined with different rates of warming for the atmosphere and sea surface of the Greenland and Iceland seas, has resulted in statistically significant reductions of approximately 20% in the magnitude of the winter air–sea heat fluxes since 1979. We also show that modes of climate variability other than the North Atlantic Oscillation (NAO; refs 3, 4, 5, 6, 7) are required to fully characterize the regional air–sea interaction. Mixed-layer model simulations imply that further decreases in atmospheric forcing will exceed a threshold for the Greenland Sea whereby convection will become depth limited, reducing the ventilation of mid-depth waters in the Nordic seas. In the Iceland Sea, further reductions have the potential to decrease the supply of the densest overflow waters to the AMOC (ref. 8). Curry, J. A. et al. Seaflux. Bull. Am. Meteorol. Soc. 85, 409–424 (2004). Mauritzen, C. Production of dense overflow waters feeding the North Atlantic across the Greenland-Scotland Ridge.1. Evidence for a revised circulation scheme. Deep-Sea Res. I 43, 769–806 (1996). Dickson, B. From the Labrador Sea to global change. Nature 386, 649–650 (1997). Hurrell, J. W. Decadal trends in the North-Atlantic Oscillation—regional temperatures and precipitation. Science 269, 676–679 (1995). Jahnke-Bornemann, A. & Bruemmer, B. The Iceland-Lofotes pressure difference: Different states of the North Atlantic low-pressure zone. Tellus A 61, 466–475 (2009). Moore, G. W. K., Renfrew, I. A. & Pickart, R. S. Spatial distribution of air–sea heat fluxes over the sub-polar North Atlantic Ocean. Geophys. Res. Lett. 39, ...

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