Postglacial paleoceanography of the western Barents Sea : Implications for alkenone-based sea surface temperatures and primary productivity

Unidad de excelencia María de Maeztu MdM-2015-0552 The increasing influence of Atlantic Water (AW) in the Barents Sea, a process known as "Atlantification", is gradually decreasing sea ice cover in the region. Ongoing global climate warming is likely to be one of its drivers, but to furthe...

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Bibliographic Details
Published in:Quaternary Science Reviews
Main Authors: Łącka, Magdalena, Cao, Min, Rosell Melé, Antoni, Pawłowska, Joanna, Kucharska, Małgorzata, Forwick, Matthias, Zajączkowski, Marek
Format: Article in Journal/Newspaper
Language:English
Published: 2019
Subjects:
Alkenones
Stratification
Holocene
Sea ice decrease
Global warming
North Atlantic Current
Arctic
Barents Sea
Storfjordrenna
Svalbard
north atlantic current
North Atlantic
Sea ice
Zooplankton
Spitsbergen
Online Access:https://ddd.uab.cat/record/223226
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Summary:Unidad de excelencia María de Maeztu MdM-2015-0552 The increasing influence of Atlantic Water (AW) in the Barents Sea, a process known as "Atlantification", is gradually decreasing sea ice cover in the region. Ongoing global climate warming is likely to be one of its drivers, but to further understand the role of natural variability and the biogeochemical impacts of the inflow of AW into the western Barents Sea, we reconstructed sea surface temperatures (SSTs) and primary productivity in Storfjordrenna, a climatically sensitive area south of Spitsbergen, between approximately 13,950 cal yr BP and 1300 cal yr BP. The alkenone U proxy has been applied to reconstruct SSTs, and the alkenone accumulation rate in marine sediments has been used to infer changes in primary productivity. Our data show that the SST increase was concomitant with the progressive loss of sea ice cover and an increase in primary productivity in the western Barents Sea. We interpret these changes as reflecting the increasing influence of AW in the area as the ice sheets retreated in Svalbard. The transition from the Arctic to the Atlantic domain first occurred after 11,500 cal yr BP, as the Arctic Front moved eastward of the study site but with considerable variability in surface ocean conditions. High SSTs at approximately 6400 cal yr BP may have led to limited winter surface cooling, likely inhibiting convective mixing and the return of nutrients to the euphotic zone and/or enhanced organic matter consumption by zooplankton due to an earlier light signal in the ice-free Storfjordrenna. During the late Holocene (3600-1300 cal yr BP), low insolation facilitated sea ice formation and thus brine production. The former may have launched convective water mixing and increased nutrient resupply to the sea surface, consequently enhancing primary productivity in Storfjordrenna. We propose that, on the basis of the paleoceanographic evidence, the modern increasing inflow of warm AW and the disappearance of pack ice on the Eurasian continental shelf ...

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