Impact of Cyclonic Wind Anomalies Caused by Massive Winter Sea Ice Retreat in the Barents Sea on Atlantic Water Transport Toward the Arctic: A Model Study

Heukamp, Finn Ole; Kanzow, Torsten; Wang, Qiang; Wekerle, Claudia; Gerdes, Rüdiger

doi:10.1029/2022jc019045

Cited by 7 publications

(17 citation statements)

References 62 publications

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“…This facilitates for example the occurrence of break-up events under strong wind conditions (Rheinlaender et al, 2022) and could lead to a future intensification of cyclone impacts on sea ice. The Arctic sea ice retreat and related changes in ocean-atmosphere heat fluxes in winter can potentially also impact the atmosphere by favoring local cyclonic circulation conditions (Heukamp et al, 2023) and intensified winter storms (Crawford et al, 2022), creating possible feedback loops involving cyclones and sea ice.A better understanding of how cyclone impacts on sea ice are affected by these "new Arctic" conditions can help to improve short-term sea ice forecasts during cyclone events. Such forecasts are important for Arctic navigation,…”

mentioning

confidence: 99%

Cyclone Impacts on Sea Ice Concentration in the Atlantic Arctic Ocean: Annual Cycle and Recent Changes

Aue,

Rinke

2023

Geophysical Research Letters

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We quantify sea ice concentration (SIC) changes related to synoptic cyclones separately for each month of the year in the Greenland, Barents and Kara Seas for 1979–2018. We find that these SIC changes can be statistically significant throughout the year. However, their strength varies from region to region and month to month, and their sign strongly depends on the considered time scale (before/during vs. after cyclone passages). Our results show that the annual cycle of cyclone impacts on SIC is related to varying cyclone intensity and traversed sea ice conditions. We further show that significant changes in these cyclone impacts have manifested in the last 40 years, with the strongest changes occurring in October and November. For these months, SIC decreases before/during cyclones have more than doubled in magnitude in the Barents and Kara Seas, while SIC increases following cyclones have weakened (intensified) in the Barents Sea (Kara Sea).

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confidence: 99%

Cyclone Impacts on Sea Ice Concentration in the Atlantic Arctic Ocean: Annual Cycle and Recent Changes

Aue,

Rinke

2023

Geophysical Research Letters

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“…Therefore, it is proposed that the regional wind forcing not only promotes variability in the WSC that is advected westwards, but also affects the strength and behavior of RAW pathways through which all AIW passes. Heukamp et al (2023) also found that because more AW was transported westwards along more southerly pathways, less heat entered the Central Arctic Ocean. This suggests that both the AW temperature anomalies in the WSC and the behavior of the recirculation pathways by which AW is advected across Fram Strait ultimately controls the AIW on the NEG continental shelf.…”

Section: Recirculation Branchesmentioning

confidence: 92%

“…This export however, has reduced in the last decades, attributed primarily to the reduction of sea ice thickness in Fram Strait which is driven mainly by atmospheric warming (Sumata et al, 2022(Sumata et al, , 2023. The shift in sea ice regime results in a strengthening of the northwards transport of AW to the Nordic Seas and Arctic Ocean (Polyakov et al, 2017;Wang et al, 2020), and is linked to changes in the atmospheric circulation (Heukamp et al, 2023;Smedsrud et al, 2022;Wang et al, 2021).…”

mentioning

confidence: 99%

Shifts of the Recirculation Pathways in Central Fram Strait Drive Atlantic Intermediate Water Variability on Northeast Greenland Shelf

McPherson,

Wekerle,

Kanzow

2023

JGR Oceans

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Increased oceanic heat transport plays a key role in the accelerated mass loss of Greenland's marine‐terminating glaciers. The melt rate of major glaciers in Northeast Greenland (NEG) is controlled by ocean variability, in particular warm Atlantic Intermediate Water (AIW), on the continental shelf. A high‐resolution configuration of the ocean sea‐ice model FESOM2.1 is assessed at local and regional scales, and used to investigate the drivers of AIW temperature variability on the NEG continental shelf. The seasonal to decadal variability of AIW is characterized, featuring both pronounced interannual fluctuations and a long‐term warming trend. A major source of AIW is Atlantic Water (AW) originating from the West Spitsbergen Current that recirculates in Fram Strait. AW anomalies are advected westwards and partly control the AIW temperatures on the continental shelf. Increased AIW temperatures are also connected to pronounced northern and central branches of recirculating AW in Fram Strait, and enhanced AW temperatures more regionally. The strengthening of the pathways brings more warmer AIW onto the northern part of the NEG continental shelf. There, it circulates anti‐cyclonically and results in shelf‐wide warming. Regional atmospheric forcing is connected to the changes in the AW circulation. The strengthening of the northern AW branches is likely caused by anticyclonic wind anomalies over the Barents Sea that drive an enhanced northward AW transport in Fram Strait. Thus, controlled by a combination of both upstream and regionally forced circulation conditions, the changes in local AIW temperatures may also affect the oceanic heat transport reaching the Central Arctic Ocean.

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“…On one hand, CHL has weakened in recent years, leading to increased winter ventilation and reduced winter ice formation (Polyakov et al 2017, Li and Fedorov 2021, Tesi et al 2021. On the other hand, the total area covered by sea ice in the Barents Sea has decreased by nearly half in recent decades, and most of the sea ice currently found in the Barents Sea is blown in from the central Arctic (Onarheim et al 2015, Stroeve and Notz 2018, Smedsrud et al 2022, Heukamp et al 2023, Rieke et al 2023 The melting of sea ice may trigger changes in sea stratification, and when sea ice melts, it replenishes the freshwater layer above the CHL. With reduced sea ice, there is less freshwater, resulting in weakened stratification between ocean layers.…”

Section: Introductionmentioning

confidence: 99%

“…Winter storms can accelerate the loss of sea ice in the Arctic, and strong wind fields have an important impact on the Atlantic Water transport in the Arctic Ocean, further intensifying the process of Atlantification (Polyakov et al 2013, Graham et al 2019, Heukamp et al 2023. However, there is limited research on these phenomena, and the Arctic hosts a highly active weather system known as Arctic cyclones, with lifecycles ranging from a few hours to several days (Keegan 1958, Serreze 1995, Simmonds and Li 2021, Valkonen et al 2021.…”

Section: Introductionmentioning

confidence: 99%

Cold season Arctic strong cyclones enhance Atlantification of the Arctic Ocean

Liu,

2023

Environ. Res. Lett.

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In recent years, as the Arctic Ocean's warming trend has accelerated, there has been increasing attention on the process of Atlantification in the Arctic Ocean. This study focused on the Arctic Atlantic inflow zone (AAZ) as its research area. Multi-source reanalysis data and in-situ Argo float data were utilized to detect Arctic strong cyclones (ASCs) in the AAZ and analyze the resulting changes in the upper ocean. The findings reveal that during the cold season (October to March), influenced by ASCs' intensity, frequency, tracks, and the concurrent weakening of ocean stratification, these cyclones can disrupt the cold halocline layer (CHL) through mechanisms such as mixing and Ekman pumping. This process facilitates the transport of heat from the deep, warm and saline Atlantic Water within the ocean to the subsurface layers. Concurrently, ASCs during the cold season can enhance the process of Atlantification in the Arctic Ocean by intensifying the intrusion of the Barents Sea Branch. Additionally, the attenuation of oceanic stratification during ASCs is primarily driven by changes in salinity, particularly above the 100 m.

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Impact of Cyclonic Wind Anomalies Caused by Massive Winter Sea Ice Retreat in the Barents Sea on Atlantic Water Transport Toward the Arctic: A Model Study

Cited by 7 publications

References 62 publications

Cyclone Impacts on Sea Ice Concentration in the Atlantic Arctic Ocean: Annual Cycle and Recent Changes

Cyclone Impacts on Sea Ice Concentration in the Atlantic Arctic Ocean: Annual Cycle and Recent Changes

Shifts of the Recirculation Pathways in Central Fram Strait Drive Atlantic Intermediate Water Variability on Northeast Greenland Shelf

Cold season Arctic strong cyclones enhance Atlantification of the Arctic Ocean

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