Your search keyword '"1000050467859"' showing total 3 results

1. Late Holocene centennial to millennial-scale variability in lower trophic level productivity off southern Hokkaido, Japan, and its response to dissolved iron-replete Coastal Oyashio dynamics

Author

1000070448380, Kuwae, Michinobu, 1000020423618, Tsugeki, Narumi, Finney, Bruce P., 1000010285190, Tani, Yukinori, 1000050467859, Onodera, Jonaotaro, Kiyoto, Mako, Kusaka, Mitsukuni, Sagawa, Takuya, Nakamura, Yugo, Ohnishi, Hiroji, 1000030531107, Kuroda, Hiroshi, 1000030380281, Okuda, Noboru, Ohta, Tamihisa, 1000090335919, Ikehara, Minoru, 1000070332476, Irino, Tomohisa, 1000070448380, Kuwae, Michinobu, 1000020423618, Tsugeki, Narumi, Finney, Bruce P., 1000010285190, Tani, Yukinori, 1000050467859, Onodera, Jonaotaro, Kiyoto, Mako, Kusaka, Mitsukuni, Sagawa, Takuya, Nakamura, Yugo, Ohnishi, Hiroji, 1000030531107, Kuroda, Hiroshi, 1000030380281, Okuda, Noboru, Ohta, Tamihisa, 1000090335919, Ikehara, Minoru, 1000070332476, and Irino, Tomohisa

Abstract

Little is known about the dynamics of marine food chains spanning primary to higher trophic levels on centennial and longer timescales, especially where the supply of dissolved iron limits primary productivity. To elucidate the long-term dynamics of biological productivity in the Coastal Oyashio (CO), which is a major pathway for transporting dissolved iron into the western North Pacific from winter to spring, we reconstructed the lower trophic level productivity over the last 3000 years in the CO. Our results demonstrate that the concentrations and mass accumulation rates of both Chl-a (chlorophyll a and its derivatives) and biogenic opal used as proxies of primary productivity, and steryl chlorin esters (SCEs) used as that of zooplankton productivity, show a millennial-scale increasing trend and centennial-scale variability beginning ca. AD 400. SCEs were positively correlated with Chl-a, indicating that changes in zooplankton productivity were induced by bottom-up control of primary productivity. The Chl-a and SCEs showed synchronous centennial-scale patterns with a relative abundance of sea-ice-associated diatom species transported by CO, and with a ventilation index in the Okhotsk Sea Intermediate Water. This synchronous pattern indicates that lower trophic-level productivity during the spring bloom responded to the intensity of iron-replete CO.

Published

2022

2. Seasonal changes in the population structure of dominant planktonic copepods collected using a sediment trap moored in the western Arctic Ocean

Author

1000090712159, Matsuno, Kohei, 1000050344495, Yamaguchi, Atsushi, 1000000756489, Fujiwara, Amane, 1000050467859, Onodera, Jonaotaro, 1000050722550, Watanabe, Eiji, 1000070344281, Harada, Naomi, 1000030359153, Kikuchi, Takashi, 1000090712159, Matsuno, Kohei, 1000050344495, Yamaguchi, Atsushi, 1000000756489, Fujiwara, Amane, 1000050467859, Onodera, Jonaotaro, 1000050722550, Watanabe, Eiji, 1000070344281, Harada, Naomi, 1000030359153, and Kikuchi, Takashi

Abstract

Winter ice cover of the Arctic Ocean makes year-round zooplankton sampling by plankton net a difficult task. Therefore, the collection of copepods with a sediment trap can be a powerful tool. In the present study, we analysed the seasonal changes in the population structures of five dominant planktonic copepods (Oncaea parila, Calanus hyperboreus, Metridia longa, Paraeuchaeta glacialis and Heterorhabdus norvegicus), which were collected using a sediment trap rotated at 10-15day intervals moored at 184-260m in the Northwind Abyssal Plain (75 degrees 00N, 162 degrees 00W) of the western Arctic Ocean from October 2010 to September 2012. Oncaea parila C6F with egg sacs occurred throughout the year, and the total abundance and composition of early copepodid stages (C1-C3) had two peaks each year. Calanus hyperboreus was dominated by C6F throughout the year, and their maturation was observed during February to May. Metridia longa C6F had a clear seasonality in lipid accumulation and gonad maturation: high lipid accumulation was observed from October to February, whereas gonad maturation occurred from March to September. Paraeuchaeta glacialis C6F also showed seasonality in lipid accumulation and gonad maturation, although their seasonal patterns varied from those of M. longa: high lipid individuals were abundant from February to April and mature individuals dominated from October to November. Heterorhabdus norvegicus showed seasonal changes in population structure as well: C1, C5, and C6M dominated from April to May, November to February and August to October, respectively. The life cycle patterns of these species are compared with those reported from other areas. While the results obtained by a sediment trap are inevitably subject to collection bias (i.e. passive collection at a fixed depth), a sediment trap should be considered as a powerful tool for the evaluation of the life cycle of planktonic copepods, especially in ice-covered oceans.

Published

2015

3. Seasonal changes in mesozooplankton swimmers collected by sediment trap moored at a single station on the Northwind Abyssal Plain in the western Arctic Ocean

Author

1000090712159, Matsuno, Kohei, 1000050344495, Yamaguchi, Atsushi, 1000000756489, Fujiwara, Amane, 1000050467859, Onodera, Jonaotaro, Watanabe, E., 1000080271013, Imai, Ichiro, 1000040360755, Chiba, Sanae, 1000070344281, Harada, Naomi, 1000030359153, Kikuchi, Takashi, 1000090712159, Matsuno, Kohei, 1000050344495, Yamaguchi, Atsushi, 1000000756489, Fujiwara, Amane, 1000050467859, Onodera, Jonaotaro, Watanabe, E., 1000080271013, Imai, Ichiro, 1000040360755, Chiba, Sanae, 1000070344281, Harada, Naomi, 1000030359153, and Kikuchi, Takashi

Abstract

To examine seasonal changes in the mesozooplankton community, analyses were made on the swimmer samples (>1 mm) collected by a sediment trap mooring at 184 m depth on the Northwind Abyssal Plain in the western Arctic Ocean during October 2010–September 2011. The zooplankton swimmer flux ranged from 5 to 44 ind. m−2 day−1 and was greater during July to October; copepods were the dominant taxon. Based on the zooplankton swimmer flux, cluster analysis classified samples into three groups (A, B-1 and B-2). The occurrence of each group showed clear seasonality; group A was observed during July to October, group B-1 was seen in November to January and group B-2 during March to June. The seasonal variability in population structures of four dominant copepod swimmers was clearly different between the species. Most Calanus hyperboreus were copepodid stage 6 female (C6F) throughout the year. For Metridia longa and Paraeuchaeta glacialis, C6Fs dominated during January to May, and early copepodid stages increased during June to October. Heterorhabdus norvegicus was dominated by stage C5 during November to February, and C6F/M during March to May. Since Pacific copepods (Neocalanus cristatus) occurred in significant number during August–September, possible causes are discussed.

Published

2014