Reproduction of the Arctic copepod Calanus hyperboreus in the Greenland Sea-field and laboratory observations

Abstract. This study explores a link between the long-term variations in the integral sea ice volume (SIV) in the Greenland Sea and oceanic processes. Using the Pan-Arctic Ice Ocean Modeling and Assimilation System (PIOMAS, 1979–2016), we show that the increasing sea ice volume flux through Fram Strait goes in parallel with a decrease in SIV in the Greenland Sea. The overall SIV loss in the Greenland Sea is 113 km3 per decade, while the total SIV import through Fram Strait increases by 115 km3 per decade. An analysis of the ocean temperature and the mixed-layer depth (MLD) over the climatic mean area of the winter marginal sea ice zone (MIZ) revealed a doubling of the amount of the upper-ocean heat content available for the sea ice melt from 1993 to 2016. This increase alone can explain the SIV loss in the Greenland Sea over the 24-year study period, even when accounting for the increasing SIV flux from the Arctic. The increase in the oceanic heat content is found to be linked to an increase in temperature of the Atlantic Water along the main currents of the Nordic Seas, following an increase in the oceanic heat flux from the subtropical North Atlantic. We argue that the predominantly positive winter North Atlantic Oscillation (NAO) index during the 4 most recent decades, together with an intensification of the deep convection in the Greenland Sea, is responsible for the intensification of the cyclonic circulation pattern in the Nordic Seas, which results in the observed long-term variations in the SIV.

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Origin of Authigenic Mn-Fe Carbonates and Pore-Water Evolution in Marine Sediments: Evidence from Cenozoic Strata of the Arctic Ocean and Norwegian-Greenland Sea (ODP Leg 151)

Journal of Sedimentary Research ◽

10.1306/2dc40930-0e47-11d7-8643000102c1865d ◽

2000 ◽

Vol 70 (3) ◽

pp. 682-699 ◽

Cited By ~ 27

Author(s):

N. Chow ◽

S. Morad ◽

I. S. Al-Aasm

Keyword(s):

Arctic Ocean ◽

Pore Water ◽

Marine Sediments ◽

The Arctic ◽

Greenland Sea ◽

The Arctic Ocean

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Relationships linking satellite-retrieved ocean color data with atmospheric components in the Arctic

10.5194/egusphere-egu2020-19377 ◽

2020 ◽

Author(s):

Marjan Marbouti ◽

Sehyun Jang ◽

Silvia Becagli ◽

Tuomo Nieminen ◽

Gabriel Navarro ◽

...

Keyword(s):

Sea Ice ◽

Barents Sea ◽

Ocean Color ◽

Particle Formation ◽

The Arctic ◽

Ice Melting ◽

New Particle Formation ◽

Greenland Sea ◽

Chl A ◽

Color Data

<p>We examined the relationships linking in-situ measurements of gas-phase methanesulfonic acid (MSA), sulfuric acid (SA), iodic acid (HIO3), Highly Oxidized Organic Molecules (HOM) and aerosol size-distributions with satellite-derived chlorophyll (Chl-a) and oceanic primary production (PP). Atmospheric data were collected at Ny-&#197;lesund site during spring-summer 2017 (30th March-4th August). We compared ocean color data from Barents Sea and Greenland Sea with concentrations of low-volatile vapours and new particle formation. The aim is to understand the main factors controlling the concentrations of atmospheric components in the Arctic in different ocean domains and seasons. Early phytoplanktonic bloom starting in April at the marginal ice zone caused Chl-a and PP in the Barents Sea to be higher than in the Greenland Sea during spring, whereas the pattern was opposite in summer. We found the correlation between ocean color data (Chl-a and PP) and MSA decreasing from spring to summer in Barents Sea and increasing in Greenland Sea. This establishes relationship between sea ice melting and phytoplanktonic bloom, which starts by sea ice melting. Similar pattern was observed for SA. Also HIO3 in both ocean domains correlated with Chl-a and PP during spring time. Greenland Sea was more active than Barents Sea. These results suggest that marine phytoplankton metabolism is an important source of MSA and SA, as expected, but also a source of HIO3 precursors (such as I2). HOMs had low correlation with ocean color parameters in comparison to other atmospheric vapours in this study both in spring and summer. The plausible explanation for low correlation is that the primary source of Volatile Organic Compounds (VOC) &#8211; precursors of HOM &#8211; is the soil of Svalbard archipelago rather than ocean. During spring, nucleation mode particles were found to correlate with Chl-a at Barents Sea and with PP at Greenland Sea. This means that biogenic productivity has a strong impact on new particle formation in spring although small particles are not related to biogenic parameters in summer.</p>

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Reproduction of the Arctic copepodCalanus hyperboreus in the Greenland Sea-field and laboratory observations

Polar Biology ◽

10.1007/bf02329209 ◽

1996 ◽

Vol 16 (3) ◽

pp. 209-219 ◽

Cited By ~ 77

Author(s):

Hans-Jürgen Hirche ◽

Barbara Niehoff

Keyword(s):

The Arctic ◽

Greenland Sea

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Long-term experiments on lifespan, reproductive activity and timing of reproduction in the Arctic copepod Calanus hyperboreus

Marine Biology ◽

10.1007/s00227-013-2242-4 ◽

2013 ◽

Vol 160 (9) ◽

pp. 2469-2481 ◽

Cited By ~ 25

Author(s):

Hans-Juergen Hirche

Keyword(s):

Reproductive Activity ◽

The Arctic ◽

Timing Of Reproduction ◽

Long Term Experiments ◽

Calanus Hyperboreus

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Soundscape and ambient noise levels of the Arctic waters around Greenland

Scientific Reports ◽

10.1038/s41598-021-02255-6 ◽

2021 ◽

Vol 11 (1) ◽

Author(s):

Michael Ladegaard ◽

Jamie Macauley ◽

Malene Simon ◽

Kristin L. Laidre ◽

Aleksandrina Mitseva ◽

...

Keyword(s):

Ambient Noise ◽

Anthropogenic Activities ◽

Open Water ◽

Anthropogenic Sources ◽

The Arctic ◽

Underwater Noise ◽

Noise Levels ◽

Greenland Sea ◽

Mammal Species ◽

Seismic Surveys

AbstractA longer Arctic open water season is expected to increase underwater noise levels due to anthropogenic activities such as shipping, seismic surveys, sonar, and construction. Many Arctic marine mammal species depend on sound for communication, navigation, and foraging, therefore quantifying underwater noise levels is critical for documenting change and providing input to management and legislation. Here we present long-term underwater sound recordings from 26 deployments around Greenland from 2011 to 2020. Ambient noise was analysed in third octave and decade bands and further investigated using generic detectors searching for tonal and transient sounds. Ambient noise levels partly overlap with previous Arctic observations, however we report much lower noise levels than previously documented, specifically for Melville Bay and the Greenland Sea. Consistent seasonal noise patterns occur in Melville Bay, Baffin Bay and Greenland Sea, with noise levels peaking in late summer and autumn correlating with open water periods and seismic surveys. These three regions also had similar tonal detection patterns that peaked in May/June, likely due to bearded seal vocalisations. Biological activity was more readily identified using detectors rather than band levels. We encourage additional research to quantify proportional noise contributions from geophysical, biological, and anthropogenic sources in Arctic waters.

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Role of cabbeling in water densification in the Greenland Basin

Ocean Science ◽

10.5194/os-5-247-2009 ◽

2009 ◽

Vol 5 (3) ◽

pp. 247-257 ◽

Cited By ~ 2

Author(s):

Y. Kasajima ◽

T. Johannessen

Keyword(s):

Barents Sea ◽

Water Mass ◽

Cold Water ◽

Maximum Velocity ◽

The Arctic ◽

Intermediate Water ◽

Greenland Sea ◽

Velocity Magnitude ◽

Basin Scale ◽

Greenland Basin

Abstract. The effects of cabbeling mixing on water mass modification in the Greenland Sea were explored by hydrographic observations across the Greenland Basin in summer 2006. The neutral surface was chosen as a reference frame, and the strength of cabbeling mixing was quantified by the dianeutral velocity magnitude. Active cabbeling spots were detected with the criterion of the velocity magnitude >1 m/day, and four active cabbeling areas were identified; the west of Bear Island (SB), the Arctic Frontal Zone (AFZ), the central Greenland Sea (CG) and the western Greenland Sea (WG). The most vigorous cabbeling mixing was found at SB, where warm North Atlantic Water (NAW) mixed with cold water from the Barents Sea, inducing a maximum velocity of 7.5 m/day and a maximum density gain of 4.7×10−3 kg/m3. At AFZ and CG, the mixing took place between NAW, modified NAW and Arctic Intermediate Water (AIW), and the density gain at these fronts were 1.5×10−3 kg/m3 (AFZ) and 1.3×10−3 kg/m3 (CG). In the western Greenland Sea, the active cabbeling spots were widely separated and mixing appeared to be rather weak, with a maximum velocity of 2.5 m/day. The mixing source waters at WG were modified NAW, AIW and even denser water, and the density gain in this area was 0.4×10−3 kg/m3. The deepest mixing produced water whose density is equivalent to that of the dense water of the basin, indicating that cabbeling in the western Greenland Sea contributed directly to basin-scale water densification. The water mass modification rate was the highest at AFZ (about 8.0 Sv), suggesting that cabbeling may play an important role in water transformation in the Greenland Basin.

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