Effects of Atlantification and changing sea‐ice dynamics on zooplankton community structure and carbon flux between 2000 and 2016 in the eastern Fram Strait

The collection of zooplankton swimmers and sinkers in time‐series sediment traps provides unique insight into year‐round and interannual trends in zooplankton population dynamics. These samples are particularly valuable in remote and difficult to access areas such as the Arctic Ocean, where samples...

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Published inLimnology and oceanography Vol. 68; pp. S39 - S53
Main Authors Ramondenc, Simon, Nöthig, Eva‐Maria, Hufnagel, Lili, Bauerfeind, Eduard, Busch, Kathrin, Knüppel, Nadine, Kraft, Angelina, Schröter, Franz, Seifert, Miriam, Iversen, Morten H.
Format Journal Article
LanguageEnglish
Published Hoboken, USA John Wiley & Sons, Inc 01.06.2023
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Summary:The collection of zooplankton swimmers and sinkers in time‐series sediment traps provides unique insight into year‐round and interannual trends in zooplankton population dynamics. These samples are particularly valuable in remote and difficult to access areas such as the Arctic Ocean, where samples from the ice‐covered season are rare. In the present study, we investigated zooplankton composition based on swimmers and sinkers collected by sediment traps at water depths of 180–280, 800–1320, and 2320–2550 m, over a period of 16 yr (2000–2016) at the Long‐Term Ecological Research observatory HAUSGARTEN located in the eastern Fram Strait (79°N, 4°E). The time‐series data showed seasonal and interannual trends within the dominant zooplankton groups including copepoda, foraminifera, ostracoda, amphipoda, pteropoda, and chaetognatha. Amphipoda and copepoda dominated the abundance of swimmers while pteropoda and foraminifera were the most important sinkers. Although the seasonal occurrence of these groups was relatively consistent between years, there were notable interannual variations in abundance, suggesting the influence of various environmental conditions such as sea‐ice dynamic and lateral advection of water masses, for example, meltwater and Atlantic water. Statistical analyses revealed a correlation between the Arctic dipole climatic index and sea‐ice dynamics (i.e., ice coverage and concentration), as well as the importance of the distance from the ice edge on swimmer composition patterns and carbon export.
Bibliography:Author Contribution Statement
S.R. wrote the paper together with E.‐M.N., L.H., and M.H.I. E.B., K.B, A.K., N.K., M.S., and F.S. provided, respectively, delivered considerable amounts of counting data to the manuscript, as well as picked zooplankton for hours during many months or even years. All authors were involved in the discussion about the long‐term perspective of environmental change in the Arctic Ocean. All authors revised and approved the manuscript.
ISSN:0024-3590
1939-5590
DOI:10.1002/lno.12192