Wintertime Water Mass Transformation in the Western Iceland and Greenland Seas

Huang, Jin‐ding; Pickart, Robert S.; Bahr, Frank; McRaven, Leah; Xu, Fanghua

doi:10.1029/2020jc016893

Cited by 6 publications

(18 citation statements)

References 52 publications

(150 reference statements)

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“…2c is likely biased by the large number of summertime hydrographic profiles; also, the re-ventilation process is a relatively new phenomenon. Furthermore, recent studies have demonstrated the importance of lateral processes on the water mass transformation in the EGC 13 , 14 . For example, the ocean response to a cold-air outbreak measured by a joint aircraft-ship campaign in winter 2018 was moderated by lateral advection and mixing near the EGC 14 .…”

Section: Resultsmentioning

confidence: 99%

“…These latter two currents contribute to the overturning in the high Arctic and also play a fundamental role in the recently documented Arctic Atlantification 37 , 38 . Recent studies have demonstrated that the AW in the EGC, as well as that in the boundary current north of Svalbard in the Amundsen Basin, can be further transformed as a result of reduced ice cover in these regions 13 , 17 , 39 . Hence, it remains unclear how much the reduction in air–sea cooling along the NwAFC might be compensated for by the re-ventilation along the EGC.…”

Section: Discussionmentioning

confidence: 99%

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Role of air-sea heat flux on the transformation of Atlantic Water encircling the Nordic Seas

2023

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The warm-to-cold densification of Atlantic Water (AW) around the perimeter of the Nordic Seas is a critical component of the Atlantic Meridional Overturning Circulation (AMOC). However, it remains unclear how ongoing changes in air-sea heat flux impact this transformation. Here we use observational data, and a one-dimensional mixing model following the flow, to investigate the role of air-sea heat flux on the cooling of AW. We focus on the Norwegian Atlantic Slope Current (NwASC) and Front Current (NwAFC), where the primary transformation of AW occurs. We find that air-sea heat flux accounts almost entirely for the net cooling of AW along the NwAFC, while oceanic lateral heat transfer appears to dominate the temperature change along the NwASC. Such differing impacts of air-sea interaction, which explain the contrasting long-term changes in the net cooling along two AW branches since the 1990s, need to be considered when understanding the AMOC variability.

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Section: Resultsmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

Role of air-sea heat flux on the transformation of Atlantic Water encircling the Nordic Seas

2023

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“…Furthermore, our observations indicate that, in the interior regime, surface cooling dominated the response with less influence from lateral effects. (We note that isolated eddies shed from the boundary current can modulate the ML response in the interior Iceland and Greenland Seas, as demonstrated by Huang et al ., 2021. )…”

Section: Impacts On the Ocean Mixed Layermentioning

confidence: 98%

“…(1986). It has previously been successfully used to simulate changes in ML properties in the western Nordic Seas (e.g., Moore et al ., 2015; Våge et al ., 2018; Brakstad et al ., 2019; Huang et al ., 2021). Here we use CTD profiles from the base of both survey triangles during the pre‐ and early‐CAO period as initial conditions, and apply atmospheric forcing from ERA5.…”

Section: Impacts On the Ocean Mixed Layermentioning

confidence: 99%

“…Some of these patches reflect changes in the distribution of sea ice and associated colder surface waters, but some appear to reflect other processes such as the upward mixing of warmer subsurface Atlantic‐origin waters, or lateral advection from eddies. Numerous eddies were observed in the hydrographic data (Huang et al ., 2021) and these are known to be an important vehicle for heat transport in such marginal seas (Spall, 2011).…”

Section: Impacts On the Ocean Mixed Layermentioning

confidence: 99%

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Coupled atmosphere–ocean observations of a cold‐air outbreak and its impact on the Iceland Sea

Renfrew

Huang

Semper

et al. 2023

Quart J Royal Meteoro Soc

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Marine cold-air outbreaks (CAOs) are vigorous equatorward excursions of cold air over the ocean, responsible for the majority of wintertime oceanic heat loss from the subpolar seas of the North Atlantic. However, the impact of individual CAO events on the ocean is poorly understood. Here we present the first coupled observations of the atmosphere and ocean during a wintertime CAO event, between 28 February and 13 March 2018, in the subpolar North Atlantic region.Comprehensive observations are presented from five aircraft flights, a research vessel, a meteorological buoy, a subsurface mooring, an ocean glider, and an Argo float. The CAO event starts abruptly with substantial changes in temperature, humidity and wind throughout the atmospheric boundary layer. The CAO is well mixed vertically and, away from the sea-ice edge, relatively homogeneous spatially. During the CAO peak, higher sensible heat fluxes occupy at least the lowest 200 m of the atmospheric boundary layer, while higher latent heat fluxes are confined to the surface layer. The response of the ocean to the CAO is spatially dependent. In the interior of the Iceland Sea the mixed layer cools, while in the boundary current region it warms. In both locations, the mixed layer deepens and becomes more saline. Combining our observations with one-dimensional mixed-layer modelling, we show that in the interior of the Iceland Sea, atmospheric forcing dominates the ocean response. In contrast, in the boundary current region lateral advection and mixing counteract the short-term impact of the atmospheric forcing. Time series observations of the late-winter period illustrate a highly variable ocean mixed layer, with lateral advection and mixing often masking the ocean's general cooling and deepening response to individual CAO events.

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Water mass transformation in the Iceland Sea: Contrasting two winters separated by four decades

Våge

Semper

Valdimarsson

et al. 2022

Deep Sea Research Part I: Oceanographic Research Papers

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Wintertime Water Mass Transformation in the Western Iceland and Greenland Seas

Cited by 6 publications

References 52 publications

Role of air-sea heat flux on the transformation of Atlantic Water encircling the Nordic Seas

Role of air-sea heat flux on the transformation of Atlantic Water encircling the Nordic Seas

Coupled atmosphere–ocean observations of a cold‐air outbreak and its impact on the Iceland Sea

Water mass transformation in the Iceland Sea: Contrasting two winters separated by four decades

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