The northern limit of spawning by Atlantic eels (<I>Anguilla</I> spp.) in the Sargasso Sea in relation to thermal fronts and surface water masses

AbstractPlastic pollution is globally recognised as a threat to marine ecosystems, habitats, and wildlife, and it has now reached remote locations such as the Arctic Ocean. Nevertheless, the distribution of microplastics in the Eurasian Arctic is particularly underreported. Here we present analyses of 60 subsurface pump water samples and 48 surface neuston net samples from the Eurasian Arctic with the goal to quantify and classify microplastics in relation to oceanographic conditions. In our study area, we found on average 0.004 items of microplastics per m3 in the surface samples, and 0.8 items per m3 in the subsurface samples. Microplastic characteristics differ significantly between Atlantic surface water, Polar surface water and discharge plumes of the Great Siberian Rivers, allowing identification of two sources of microplastic pollution (p < 0.05 for surface area, morphology, and polymer types). The highest weight concentration of microplastics was observed within surface waters of Atlantic origin. Siberian river discharge was identified as the second largest source. We conclude that these water masses govern the distribution of microplastics in the Eurasian Arctic. The microplastics properties (i.e. abundance, polymer type, size, weight concentrations) can be used for identification of the water masses.

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The Relationship between Surface Water Masses, Oceanographic Fronts and Paleoclimatic Proxies in Surface Sediments of the Greenland, Iceland, Norwegian Seas

Carbon Cycling in the Glacial Ocean: Constraints on the Ocean’s Role in Global Change ◽

10.1007/978-3-642-78737-9_4 ◽

1994 ◽

pp. 61-85 ◽

Cited By ~ 76

Author(s):

Truls Johannessen ◽

Eystein Jansen ◽

Astrid Flatøy ◽

Ana Christina Ravelo

Keyword(s):

Surface Water ◽

Surface Sediments ◽

Water Masses ◽

The Relationship

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New clues on the Atlantic eels spawning behavior and area: the Mid-Atlantic Ridge hypothesis

Scientific Reports ◽

10.1038/s41598-020-72916-5 ◽

2020 ◽

Vol 10 (1) ◽

Author(s):

Yu-Lin K. Chang ◽

Eric Feunteun ◽

Yasumasa Miyazawa ◽

Katsumi Tsukamoto

Keyword(s):

Ocean Circulation ◽

Specific Area ◽

Migration Behavior ◽

Sargasso Sea ◽

Distribution Fitting ◽

Particle Tracking Method ◽

Spawning Area ◽

Mid Atlantic Ridge ◽

And Migration ◽

Atlantic Eels

Abstract The Sargasso Sea has long been considered as the only spawning area for Atlantic eels, despite the absence of direct observations. The present study raises a novel scenario, deviating from Schmidt’s dogma, begins with a review of historical and recent observations that were combined to build up a global theory on spawning ecology and migration behavior of Atlantic eels. From this, it is argued that a favorable spawning area could be located eastward of Sargasso Sea at the intersection between the Mid-Atlantic Ridge and the oceanic fronts. Ocean circulation models combined with 3D particle-tracking method confirmed that spawning at this specific area would result in larval distribution fitting the field observation. This study explores the hypothesis that leptocephali are able to swim and orientate to reach their specific growth areas. It proposes a novel framework about spawning ecology, based on orientation, navigation and meeting cues of silver eels to the spawning area. Together this framework may serve as a stepping-stone for solving the long-lasting mystery of eel reproduction which first came out 2,400 years ago and promotes the understanding of oceanic migration and reproduction of marine organisms.

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Surface waters properties in the Laptev and the East-Siberian Seas in summer 2018 from in situ and satellite data

10.5194/os-2019-60 ◽

2019 ◽

Author(s):

Anastasiia Tarasenko ◽

Alexandre Supply ◽

Nikita Kusse-Tiuz ◽

Vladimir Ivanov ◽

Mikhail Makhotin ◽

...

Keyword(s):

Surface Water ◽

Satellite Data ◽

Water Masses ◽

Sea Surface ◽

Ekman Transport ◽

Water Displacement ◽

Wind Speeds ◽

In Situ Data ◽

Ocean Salinity

Abstract. Variability of surface water masses of the Laptev and the East-Siberian seas in August–September 2018 is studied using in situ and satellite data. In situ data was collected during ARKTIKA-2018 expedition and then completed with satellite estimates of sea surface temperature (SST) and salinity (SSS), sea surface height, satellite-derived wind speeds and sea ice concentrations. Derivation of SSS is still challenging in high latitude regions, and the quality of Soil Moisture and Ocean Salinity (SMOS) SSS retrieval was improved by applying a threshold on SSS weekly error. The validity of SST and SSS products is demonstrated using ARKTIKA-2018 continuous thermosalinograph measurements and CTD casts. The surface gradients and mixing of river and sea waters in the free of ice and ice covered areas is described with a special attention to the marginal ice zone. The Ekman transport was calculated to better understand the pathway of surface water displacement. T-S diagram using surface satellite estimates shows a possibility to investigate the surface water masses transformation in detail.

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The Identification and Nomenclature of the Surface Water Masses in the Tasman Sea (Data to the End of 1954)

Marine and Freshwater Research ◽

10.1071/mf9570369 ◽

1957 ◽

Vol 8 (4) ◽

pp. 369 ◽

Cited By ~ 24

Author(s):

DJ Rochford

Keyword(s):

Surface Water ◽

Sea Water ◽

Maximum Velocity ◽

Water Masses ◽

Late Winter ◽

The South ◽

Coral Sea ◽

Tasman Sea ◽

East And West ◽

Western Side

In this paper an examination of all available data on the hydrological characteristics of the Tasman Sea, prior to and including the year 1954, has permitted the identification and naming of eight surface water masses. Certain of their properties and general features of their season and region of occurrence and method of formation are summarized. Although little quantitative data are available some general features of the circulation of these water masses in the Tasman Sea are deduced from a study of their seasonal occurrence in relation to source regions. The Coral Sea water mass (chlorinity 19.60-19.70‰, temperature 20-26� C) flows from a source region in the north-west Coral Sea along the western side of the Tasman Sea and reaches maximum velocity off Sydney in October-December. The South Equatorial (chlorinity 19.50-19.60‰, temperature 24-26� C) also flows south along the western side of the Tasman Sea but reaches maximum velocity between February and March. These two water masses constitute the East Australian current. The Sub-Antarctic (chlorinity 19.15-19.30‰, temperature 10-14°C) is found at the surface in the south-eastern Tasman Sea between July and September. The Central Tasman (chlorinity 19.65-19.75‰, temperature 15-20‰C) flows to the west from its region of formation and generally flows north along the southern New South Wales coast in late winter. The South-west Tasman (chlorinity 19.50- 19.60‰, temperature 12-15°C) flows to the east in latitude 38�S. and curves south in a clockwise gyral off eastern Tasmania between October and December. The Xorth Bass Strait (chlorinity 19.66-19.75‰ temperature 12-17�C) flows from South Australia to the eastern approaches of Bass Strait. The East Central New Zealand (chlorinity 19.10-19.30‰, temperature 15-20°C) flows west through Cook Strait into the Tasman Sea in midsummer. The East and West Tasmanian (chlorinity 19.40- 19.50‰ temperature 10-14°C) form in midwinter in the southern part of Bass Strait and flow along the east and west coasts in the spring.

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