Atlantic Water Heat Transport Variability in the 20th Century Arctic Ocean From a Global Ocean Model and Observations

Muilwijk, Morven; Smedsrud, Lars H.; Ilıcak, Mehmet; Drange, Helge

doi:10.1029/2018jc014327

Cited by 83 publications

(112 citation statements)

References 121 publications

(213 reference statements)

Supporting

Mentioning

Contrasting

Order By: Relevance

“…When the IAVF is maintained only inside the Arctic Ocean in the AO_vari run, the regression of SLP on the BSO transport shows a pattern with low pressure around the Svalbard and high pressure centered at the southwestern Kara Sea (Figure 5h). The wind anomaly associated with this pattern can lower the SSH on the Svalbard side through Ekman divergence (Figure 5i), thus increasing the SSH gradient and the BSO transport, consistent to previous studies on the role of local wind forcing (Ingvaldsen et al, 2002(Ingvaldsen et al, , 2004Lien et al, 2013Lien et al, , 2017Muilwijk et al, 2018;Skagseth et al, 2011).…”

Section: Geophysical Research Letterssupporting

confidence: 90%

Ocean Heat Transport Into the Barents Sea: Distinct Controls on the Upward Trend and Interannual Variability

Wang

Wekerle

et al. 2019

Geophysical Research Letters

View full text Add to dashboard Cite

Ocean heat transport through the Barents Sea Opening (BSO) has strong impacts on the Barents Sea ice extent and the climate. In this paper we quantified the contributions from different atmospheric forcing components to the trend and interannual variability of the BSO heat transport. Ocean‐ice model simulations were conducted in which the interannual variation of atmospheric forcing was maintained only in or outside the Arctic in two different simulations. The sum of their BSO heat transport anomalies reasonably replicated the trend and variability from a hindcast simulation. The upward trend of the BSO heat transport mainly stems from the increasing ocean temperature in the subpolar North Atlantic. For the interannual variability, the local wind and upstream forcing are similarly important. The location of the Atlantic Water boundary current in the Nordic Seas, influenced by the cyclonic atmospheric circulation, is crucial in determining part of the BSO inflow variability.

show abstract

Section: Geophysical Research Letterssupporting

confidence: 90%

Ocean Heat Transport Into the Barents Sea: Distinct Controls on the Upward Trend and Interannual Variability

Wang

Wekerle

et al. 2019

Geophysical Research Letters

View full text Add to dashboard Cite

show abstract

“…Temperature fluctuations are important for the BSO heat transport, but it is dominated by volume fluctuations (Muilwijk et al, ; Smedsrud et al, ). The CRFs of the associated heat transports are calculated relative to 0 ° C, and overall, there is consistent CRF response among the models for the eastward volume and heat transport (Figure ).…”

Section: Resultsmentioning

confidence: 99%

“…Variability in the Barents Sea sea ice extent has been attributed to a number of processes, and variations in the ocean heat transport is key (Årthun et al, 2012;Li et al, 2017;Smedsrud et al, 2013;Venegas & Mysak, 2000;Zhang, 2015). These heat anomalies result from either increased volume transport in the Norwegian Atlantic Current, a poleward extension of the North Atlantic Current (Muilwijk et al, 2018;Smedsrud et al, 2013), or temperature anomalies that are either generated locally (Schlichtholz & Houssais, 2011) or advected in from the south (Årthun & Eldevik, 2016;Furevik, 2001;Holliday et al, 2008;Skagseth et al, 2008). This has motivated several studies that have explored the effect of wind forcing on the AW volume and heat transport.…”

Section: Introductionmentioning

confidence: 99%

Arctic Ocean Response to Greenland Sea Wind Anomalies in a Suite of Model Simulations

et al. 2019

Self Cite

View full text Add to dashboard Cite

Multimodel Arctic Ocean “climate response function” experiments are analyzed in order to explore the effects of anomalous wind forcing over the Greenland Sea (GS) on poleward ocean heat transport, Atlantic Water (AW) pathways, and the extent of Arctic sea ice. Particular emphasis is placed on the sensitivity of the AW circulation to anomalously strong or weak GS winds in relation to natural variability, the latter manifested as part of the North Atlantic Oscillation. We find that anomalously strong (weak) GS wind forcing, comparable in strength to a strong positive (negative) North Atlantic Oscillation index, results in an intensification (weakening) of the poleward AW flow, extending from south of the North Atlantic Subpolar Gyre, through the Nordic Seas, and all the way into the Canadian Basin. Reconstructions made utilizing the calculated climate response functions explain ∼50% of the simulated AW flow variance; this is the proportion of variability that can be explained by GS wind forcing. In the Barents and Kara Seas, there is a clear relationship between the wind‐driven anomalous AW inflow and the sea ice extent. Most of the anomalous AW heat is lost to the atmosphere, and loss of sea ice in the Barents Sea results in even more heat loss to the atmosphere, and thus effective ocean cooling. Release of passive tracers in a subset of the suite of models reveals differences in circulation patterns and shows that the flow of AW in the Arctic Ocean is highly dependent on the wind stress in the Nordic Seas.

show abstract

“…The concept and implications of polar water masses becoming closer to those typical of midlatitude oceans have also been explored on the Atlantic Ocean side of the Arctic. Mean Atlantic Water temperatures at Fram Strait and the Barents Sea Opening increased by around 1–1.5 ° C from 1980 to 2012 with long‐term trends in volume inflow estimates difficult to infer given observation limitations (Muilwijk et al, ). Recent changes in the vicinity of the Atlantic Water inflow to the Arctic Ocean, including reduced sea ice, weaker stratification, and enhanced Atlantic Water Layer heat fluxes further northeast into the Eurasian Basin, have been referred to as the Atlantification of the Arctic Ocean (Årthun et al, ; Lind et al, ; Polyakov et al, ).…”

Section: Arctic Ocean Variability Climate Change and Future Perspecmentioning

confidence: 99%

Understanding Arctic Ocean Circulation: A Review of Ocean Dynamics in a Changing Climate

2020

View full text Add to dashboard Cite

The Arctic Ocean is a focal point of climate change, with ocean warming, freshening, sea-ice decline, and circulation that link to the changing atmospheric and terrestrial environment. Major features of the Arctic and the interconnected nature of its wind-and buoyancy-driven circulation are reviewed here by presenting a synthesis of observational data interpreted from the perspective of geophysical fluid dynamics (GFD). The general circulation is seen to be the superposition of Atlantic Water flowing into and around the Arctic basin and the two main wind-driven circulation features of the interior stratified Arctic Ocean: the Transpolar Drift Stream and the Beaufort Gyre. The specific drivers of these systems, including wind forcing, ice-ocean interactions, and surface buoyancy fluxes, and their associated GFD are explored. The essential understanding guides an assessment of how Arctic Ocean structure and dynamics might fundamentally change as the Arctic warms, sea-ice cover declines, and the ice that remains becomes more mobile.

show abstract

Atlantic Water Heat Transport Variability in the 20th Century Arctic Ocean From a Global Ocean Model and Observations

Cited by 83 publications

References 121 publications

Ocean Heat Transport Into the Barents Sea: Distinct Controls on the Upward Trend and Interannual Variability

Ocean Heat Transport Into the Barents Sea: Distinct Controls on the Upward Trend and Interannual Variability

Arctic Ocean Response to Greenland Sea Wind Anomalies in a Suite of Model Simulations

Understanding Arctic Ocean Circulation: A Review of Ocean Dynamics in a Changing Climate

Contact Info

Product

Resources

About