Takahito Ikenoue, Kjell Bjørklund, Anders K. Krabberød, Shigeto Nishino, Paul Wassmann
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引用次数: 0
摘要
为了确定挪威峡湾硅质根瘤菌(放射菌属和Phaeodaria)的现今群落组成,2016年9月在挪威西南部和北部峡湾进行了浮游生物拖带研究。南区Sognefjord杂群放射虫总丰度平均为306 m - 3,北区Malangen为945 m - 3, Balsfjord为89 m - 3,均位于北极圈以内。Sognefjord杂群和Malangen中放射虫最丰富的是Sticholonche zanclea,占放射虫总丰度的78 ~ 100%(平均89%)。Sognefjord杂群中平均总寄生菌丰度为1554 m-3 Malangen为51 m-3 Balsfjord为11 m-3 Medusetta arcifera 是Sognefjord杂群中最丰富的寄生菌,占寄生菌丰度的99%,而Malangen和Balsfjord中不存在寄生菌,其中tridensprotocystis 占寄生菌丰度的96%。S的碳生物量。zanclea 以及M。分别为188µg C M - 3和438µg C M - 3,与北太平洋西部的phaeodarians的1µg C M - 3相似,高8.6倍。在Sognefjord complex中,arcifera 对有机碳的运输起着重要作用。在1982 - 1983年期间,研究区优势种Amphimelissa setosa (Nassellaria, Radiolaria)在本研究中均未出现。这可能是由自1990年以来水温升高约2°C造成的,并且可以作为与大西洋平流水变暖有关的与气候变化相关的局部温度升高的证据。
Radiolaria and Phaeodaria (siliceous Rhizaria) in south-western and northern Norwegian fjords during late summer 2016: dominant species and biomass in shallow-water assemblages
To determine the present-day community composition of siliceous Rhizaria (Radiolaria and Phaeodaria) in Norwegian fjords, plankton tows were conducted in south-western and northern Norwegian fjords in September 2016. The mean total abundance of radiolarians was 306 m–3 in the Sognefjord complex, which was the southern research site, and, in the north, 945 m–3 in Malangen and 89 m–3 in Balsfjord, both above the Arctic Circle. Sticholonche zanclea was the most abundant radiolarian in the Sognefjord complex and Malangen, accounting for 78–100% (mean 89%) of radiolarian abundance. The mean total abundance of phaeodarians was 1554 m–3 in the Sognefjord complex, 51 m–3 in Malangen and 11 m–3 in Balsfjord. Medusetta arcifera was the most abundant phaeodaria in the Sognefjord complex, accounting for >99% of phaeodarian abundance, but was absent in Malangen and Balsfjord, where Protocystis tridens accounted for >96% of phaeodarian abundance. The carbon biomass of S. zanclea and M. arcifera was 188 and 438 µg C m–3, respectively, which is similar to and 8.6 times higher than, respectively, that of phaeodarians >1 mm in the western North Pacific, suggesting that M. arcifera contributes to organic carbon transport in the Sognefjord complex. Amphimelissa setosa (Nassellaria, Radiolaria), which was a dominant species in the study area in 1982–83, was absent in the present study in all sampled fjords. This could have been caused by the approximately 2 °C increase in water temperature that has occurred since 1990 and can be taken as evidence of a climate-change-associated local temperature rise linked to the warming of advected Atlantic Water.
期刊介绍:
Since 1982, Polar Research has been the international, peer-reviewed journal of the Norwegian Polar Institute, Norway''s central institution for research, environmental monitoring and mapping of the polar regions. Aiming to promote the exchange of scientific knowledge about the Arctic and Antarctic across disciplinary boundaries, Polar Research serves an international community of researchers and managers. As an open-access journal, Polar Research makes its contents freely available to the general public.
Original primary research papers comprise the mainstay of Polar Research. Review articles, brief research notes, letters to the editor and book reviews are also included. Special issues are published from time to time.
The scope of Polar Research encompasses research in all scientific disciplines relevant to the polar regions. These include, but are not limited to, the subfields of biology, ecology, geology, oceanography, glaciology and atmospheric science. Submissions from the social sciences and those focusing on polar management and policy issues are welcome. Contributions about Antarctica are particularly encouraged.