Your search keyword '"arctic ocean"' showing total 14,061 results

1. THE NORWEGIAN TERRITORY WHERE THE RUSSIANS ARE DETERMINED TO KEEP THE RED FLAG FLYING: Tensions are mounting in Svalbard, where a Russian mining town is goading the Norwegian authorities

Subjects

Russian Invasion of Ukraine, 2022-, Coal industry -- International economic relations, Mines and mineral resources, Geography

Abstract

We are heading to the Russian-owned town of Barentsburg on the Norwegian archipelago of Svalbard, high in the Arctic Ocean, aboard the expedition ship MS Polar Girl. My Russian guide, [...]

Published

2024

2. The strategic insights of Arctic sea routes for the sustainable development of Taiwan's shipping industry.

Author

Chen, Yung-Sheng, Chen, Po-Hung, Jung, Chun-Hao, Chang, Tsai-Ling, Ye, Jia-An, and Liu, Ta-Kang

Subjects

*MARITIME shipping, *TRADE routes, *ARCTIC climate, NORTHEAST Passage, NORTHWEST Passage

Abstract

In recent years, the Arctic Ocean has been experiencing the impacts of climate change. Global warming has led to the melting of ice caps and a significant reduction in ice coverage. As a result, the Arctic Ocean has indirectly opened up two new shipping routes known as the "Northeast Passage" and the "Northwest Passage." The opening of these new routes has the potential to transform Northeast Asia into a major transshipment hub, linking the Indo-Pacific and Europe regions. Novel business models are also generated and investigated within the maritime industry. This study involved conducting semi-structured interviews with potential stakeholders from industry, government, and academia. Additionally, qualitative analysis software- NVivo11 was utilized along with grounded theory for data analysis. The rationale supporting this view includes the advantages of Taiwan's shipping industry, its strategic geographic location, and the potential for shorter shipping routes through the Arctic. Additionally, Taiwan can establish conducive conditions to enhance its international standing and diplomatic relationships concerning Arctic Ocean matters. This initiative will facilitate the sustainable development of Taiwan's maritime industry in the Arctic region. • The evolving perspectives of Taiwan's maritime and transportation industry in balancing economic and environmental considerations. • Incorporating stakeholders' feedback into policy formulation: Perspectives and insights. • Positioning and reflections on Taiwan's development strategy for the Arctic sea routes. [ABSTRACT FROM AUTHOR]

Published

2024

3. New Data on the Structure of the Laptev Sea Flank of the Gakkel Ridge (Arctic Ocean).

Author

Kaminsky, D. V., Chamov, N. P., Zhilin, D. M., Krylov, A. A., Neevin, I. A., Bujakaite, M. I., Degtyarev, K. E., Dubensky, A. S., Kaminsky, V. D., Logvina, E. A., Okina, O. I., Semenov, P. B., Kil, A. O., Pokrovsky, B. G., and Tolmacheva, T. Yu.

Subjects

*CARBONATE rocks, *MID-ocean ridges, *ISOTOPE geology, *ALLUVIAL fans, *BOTTOM water (Oceanography), *LANDSLIDES, *CALCITE

Abstract

The article provides new data on the structure of the Laptev Sea flank of the Gakkel Ridge. The intensive supply of clastic material from the Laptev Sea shelf leads to the development of a thick alluvial fan at the continental rise, which determines the structure of the bottom topography. In the northwestern direction, the influence of the fan decreases and tectonics becomes the main relief-forming factor. The bathymetric survey traced the asymmetrical rift valley of the Gakkel Ridge, the western flank of which is complicated by terraces. The presence of fault structures, bottom subsidence, extensive sediment supply, and the widespread development of subaqueous slump processes indicate the high neotectonic activity of the Laptev Sea flank of the Gakkel Ridge. For the first time in this region, numerous carbonate rocks have been discovered, the authigenic cement of which is represented by magnesian calcite or aragonite with an admixture of terrigenous material. The palynological and micropaleontological analysis of the carbonate rocks indicates the Quaternary formation of authigenic carbonate cement. An important role in the formation of authigenic carbonates was played by diagenetic solutions coming from the sedimentary cover together with methane and oxidation products of gases and organic matter. The authigenic carbonates were precipitated mainly in an isotopic equilibrium with bottom water at a temperature of about 0°C. The negative correlation between 87Sr/86Sr and δ13C indicates the presence of at least two different sources of carbonate-forming solutions. [ABSTRACT FROM AUTHOR]

Published

2024

4. The Transpolar Drift current: an ocean-ice-wind complex in rotating, spherical coordinates.

Author

Johnson, R. S.

Abstract

Starting from the governing equations for a viscous, incompressible fluid, written in a rotating, spherical coordinate system that is valid at the North Pole, the thin-shell approximation is invoked. No further approximations are needed in the derivation of the system of asymptotic equations used here. Suitable stress conditions on the upper and lower surfaces of the ice are described, leading to the construction of a solution for the Transpolar Drift current. This involves the specification of a suitable geostrophic flow, combined with an Ekman component. Then, via the stress conditions across the ice at the surface, a solution for the motion of the ice, and for the associated wind blowing over it, are obtained. In addition, the model adopted here provides a prediction for the reduction in ice thickness along the Transpolar Drift current as it passes through the Fram Strait. The formulation that we present allows considerable freedom in the choices of the various elements of the flow; the model chosen for the physical properties of the ice is particularly significant. All these aspects are discussed critically, and it is shown that many avenues for future investigation have been opened. [ABSTRACT FROM AUTHOR]

Published

2024

5. Enhanced Net Community Production With Sea Ice Loss in the Western Arctic Ocean Uncovered by Machine‐Learning‐Based Mapping.

Author

Zhou, Tianyu, Li, Yun, Ouyang, Zhangxian, Cai, Wei‐Jun, and Ji, Rubao

Abstract

In the Arctic Ocean (AO), net community production (NCP $NCP$) has displayed spatially heterogeneous responses to sea ice reduction and associated environmental changes. Using a random forest machine learning model trained with >42,000 in situ measurements and concurrent, collocated environmental predictors, we reconstructed 19 years of 8‐day, 6‐km NCP $NCP$ maps. During 2015–2021, the integrated NCP $NCP$ between late‐May and early‐September (NCPint ${}_{\mathit{int}}NCP$) over the western AO was 10.95±3.30TgC $10.95\pm 3.30\,\text{Tg}\,\mathrm{C}$ per year, with interannual variations positively tracking open water area. While the relationship between NCPint ${}_{\mathit{int}}NCP$ and open water area was quasi‐linear at high latitudes, strong nonlinearity was detected on the inflow shelf. The nonlinearity highlights that the NCPint ${}_{\mathit{int}}NCP$ increase resulted from area gain could be compounded by sea‐ice loss induced ecosystem adjustments. Additional retrospective analysis for 2003–2014 suggests a potential long‐term increase of export production and efficiency in the western AO with sea ice loss. Plain Language Summary: Net community production (NCP $NCP$) refers to the portion of phytoplankton production that remains unused by consumers and can be exported to the deeper part of the ocean. In the western Arctic Ocean (AO), NCP $NCP$ patterns are uneven due to complex interactions between the physical environment and the ecosystem. In this study, we developed a machine learning model of NCP $NCP$ in the western AO. The model used publicly available underway measurements and the associated environmental variables to create long‐term, high‐resolution maps of NCP $NCP$. For the period of 2015–2021, we found that the integrated NCP $NCP$ between late‐May and early‐September (NCPint ${}_{\mathit{int}}NCP$) was 10.95±3.30TgC $10.95\pm 3.30\,\text{Tg}\,\mathrm{C}$ per year in the western AO. NCPint ${}_{\mathit{int}}NCP$ varied from year to year and was higher when the open water area was larger. Notably, on the inflow shelf, NCPint ${}_{\mathit{int}}NCP$ increased at a faster rate than a linear relationship would suggest, due to both area expansion and ecosystem adjustments induced by sea ice loss. Our findings indicate that with long‐term sea ice loss, the western AO is likely to export more phytoplankton production to deeper ocean waters. Key Points: A multiyear, gap‐free net community production (NCP $NCP$) product was constructed using a machine learning model for the western Arctic OceanSeasonally and regionally integrated NCP $NCP$ responded to sea ice loss quasi‐linearly at high latitudes but nonlinearly on the inflow shelfCompared with the 2010s, carbon export production has increased in recent years, accompanying sea ice loss in the western Arctic Ocean [ABSTRACT FROM AUTHOR]

Published

2024

6. Vulnerability of Arctic-Boreal methane emissions to climate change.

Author

Parmentier, Frans-Jan W., Thornton, Brett F., Silyakova, Anna, and Christensen, Torben R.

Abstract

The rapid warming of the Arctic-Boreal region has led to the concern that large amounts of methane may be released to the atmosphere from its carbon-rich soils, as well as subsea permafrost, amplifying climate change. In this review, we assess the various sources and sinks of methane from northern high latitudes, in particular those that may be enhanced by permafrost thaw. The largest terrestrial sources of the Arctic-Boreal region are its numerous wetlands, lakes, rivers and streams. However, fires, geological seeps and glacial margins can be locally strong emitters. In addition, dry upland soils are an important sink of atmospheric methane. We estimate that the net emission of all these landforms and point sources may be as much as 48.7 [13.3–86.9] Tg CH4 yr−1. The Arctic Ocean is also a net source of methane to the atmosphere, in particular its shallow shelves, but we assess that the marine environment emits a fraction of what is released from the terrestrial domain: 4.9 [0.4–19.4] Tg CH4 yr−1. While it appears unlikely that emissions from the ocean surface to the atmosphere are increasing, now or in the foreseeable future, evidence points towards a modest increase from terrestrial sources over the past decades, in particular wetlands and possibly lakes. The influence of permafrost thaw on future methane emissions may be strongest through associated changes in the hydrology of the landscape rather than the availability of previously frozen carbon. Although high latitude methane sources are not yet acting as a strong climate feedback, they might play an increasingly important role in the net greenhouse gas balance of the Arctic-Boreal region with continued climate change. [ABSTRACT FROM AUTHOR]

Published

2024

7. Integrating Biofilm Growth and Degradation into a Model of Microplastic Transport in the Arctic Ocean.

Author

Golubeva, Elena and Gradova, Marina

Abstract

The present study analyzes the potential propagation trajectories and fate of floating microplastic particles released on the Kara Sea shelf. The transport of microplastics is described using a Lagrangian model based on daily 2016–2020 data obtained from numerical modeling of Arctic Ocean dynamics. A particle biofouling model is used to simulate the submergence of floating microplastic particles in the water column. The model includes a parameterization of the processes of biofilm accumulation (via collision with algae in surrounding water, algae growth) and degradation (via respiration, mortality). The behavior of microplastic particles of different sizes (0.5 and 0.01 mm) during the sinking process and subsequent rising due to biofilm degradation is examined. The simulation results reveal that particles of 0.01 mm in size display a tendency to sink immediately during the process of biofouling. However, when the biofilm degraded, the particles exhibited a rising velocity, comparable to the current vertical velocity, and the particles remained submerged in the water for long periods. In contrast, the 0.5 mm particles remained at the surface for a longer period before sinking, accumulating biofilm. Subsequently, their behavior was oscillatory in response to changes in the biofilm, rising rapidly when the biofilm decayed and sinking rapidly again as a result of biomass accumulation. In winter, the 0.5 mm particles were mostly frozen into the ice. The phenomenon of biofouling, whereby microplastic particles of various sizes sink at different depths, results in considerable variation in the subsequent pathways of these particles in the Arctic Ocean. [ABSTRACT FROM AUTHOR]

Published

2024

8. Microplastic fate in Arctic coastal waters: accumulation hotspots and role of rivers in Svalbard.

Author

Pakhomova, Svetlana, Berezina, Anfisa, Zhdanov, Igor, and Yakushev, Evgeniy

Subjects

COASTS, TERRITORIAL waters, REGIONS of freshwater influence, WATER pollution, MARINE pollution, PLASTIC marine debris

Abstract

Little is known about the role of remote and sparsely populated Arctic coastal zones in the microplastic cycle. Distribution of microplastics was studied in the Svalbard fjords in June – July 2022 with the main goal of assessing rivers' role in the fate of microplastic in Arctic coastal waters. Surface microplastics (0 – 20 cm depth, 500 – 5000 µm size) were sampled with a neuston net in triplicate per study site in parallel with sampling of subsurface microplastics with a pump system (1.5 m depth, 100 – 5000 µm size). The central part of Isfjorden and its several branches covering populated and unpopulated fjords were studied; the sampling was conducted during an intense riverine discharge in all studied sites. Maximum abundance of surface microplastics (71,400 items/km2 or 0.19 iterms/m3, 0.19 mg/m3) was found along the river plume border in the middle of populated Adventfjorden indicating importance of both local sources and surface hydrodynamics in the formation of microplastics accumulation hotspots. All other unpopulated fjords were free of the floating on the sea surface microplastics as river discharge prevented transport of microplastics inside the fjords. The highest concentration of subsurface microplastics was found in the central part of Isfjorden and the lowest – in river plume waters, which also indicates the removal of microplastics from the inner part of fjords during an intensive river discharge. Our results may suggest that Arctic rivers flowing through unpopulated areas bring clean water and thereby reduce level of microplastic pollution in the coastal waters. In contrast to the rest of the world's ocean, rivers are not the main source of microplastic pollution in the Arctic Ocean. [ABSTRACT FROM AUTHOR]

Published

2024

9. Regulatory factors and climatic impacts of marine heatwaves over the Arctic Ocean from 1982 to 2020.

Author

Zhang, Xiaojuan, Zheng, Fei, and Gong, Zhiqiang

Subjects

*MARINE heatwaves, *GEOPOTENTIAL height, *ATMOSPHERIC circulation, *ENTHALPY, *ATMOSPHERIC temperature

Abstract

Arctic warming has been substantially greater than that in the rest of the world and has had an important influence on the global climate. This study first explores the temporal and spatial evolutionary characteristics of marine heatwaves (MHWs) over the Arctic Ocean in multiyear ice (MYI), first‐year ice (FYI), and open‐water (OPW) regions from 1982 to 2020. MHWs in the Arctic Ocean show obvious spatial and seasonal variations, mainly occurring over the FYI region in the JAS (July–August–September, JAS), and their occurrences have a significant increasing trend in recent decades, accompanied by an abrupt increase since 2010. Furthermore, a multivariable network‐based method is adopted to delineate the relationship between different climatic factors and MHWs in the Arctic Ocean and the climatic impacts of MHWs. The results show that the correlations between different climatic factors and MHWs in JAS in 2010–2020 are generally stronger than those in 1982–2009, and the main influencing factors of MHWs in different ice covers are different. MHWs in the MYI region are mainly affected by freshwater dilution processes, such as sea‐ice concentrations (SIC), precipitation, and mixed‐layer salinity. For the FYI region, the 2‐m air temperature and total heat flux mainly affect MHWs by thermodynamic processes, and the 500‐hPa geopotential height affects MHWs mainly by large‐scale atmospheric circulation. The MHWs in the OPW region are mainly related to the SIC, 850‐hPa geopotential height, and 10‐m v‐wind, indicating that they are correlated with atmospheric processes and wind fields. MHWs in JAS are also revealed to reduce or delay the formation of sea ice in OND (October–November–December, OND) by storing more abnormal heat, indicating that unfrozen ocean surfaces may lead to enhanced Arctic amplification in the following seasons. [ABSTRACT FROM AUTHOR]

Published

2024

10. Decadal Changes in the Pathways of the Atlantic Water Core in the Arctic Ocean Inferred From Transient Tracers.

Author

Körtke, Wiebke, Walter, Maren, Huhn, Oliver, Kanzow, Torsten, and Rhein, Monika

Abstract

The Atlantic Water plays a major and increasing role in the heat budget of the Arctic Ocean (Atlantification). The pathways of Atlantic Water within the Arctic Ocean, and in particular their sensitivities to large‐scale atmospheric patterns such as the Arctic Oscillation, remain unclear. In this study, we used the trace gases CFC‐12 and SF6 ${\text{SF}}_{6}$ to investigate the Atlantic Water pathways during different phases of the Arctic Oscillation. We calculated tracer ages for the temperature maximum of the Atlantic Water, focusing on repeated transects (1994, 2005, 2015) in the Amerasian Basin of the Arctic Ocean. During a positive phase of the Arctic Oscillation in 1994, tracer ages were low along the Chukchi shelf due to a strong coherent boundary current. In contrast, the ages were up to 10 years higher in 2015 without this coherent current during a mixed phase of the Arctic Oscillation. Further, we identified a discontinuity in the inflow between the Makarov Basin and the Canada Basin during this phase. Tracer ages were 10 years higher in the Canada Basin, suggesting a closed circulation without direct inflow in this region. Our tracer ages generally align with previously proposed circulation schemes and water ages, with major exceptions in 2015. We have shown that the tracer ages are applicable to identify decadal changes in the Atlantic Water core pathways in the central Arctic Ocean. Plain Language Summary: The warm Atlantic Water transports heat into the Arctic Ocean, potentially melting the sea ice. The pathways of Atlantic Water within the Arctic Ocean are essential to understand in a changing climate and under changing atmospheric conditions. Our aim here is to analyze repeated transects in the Arctic Ocean to find decadal changes in the Atlantic Water core pathways. We used the anthropogenic trace gases CFC‐12 and SF6 ${\text{SF}}_{6}$ to calculate tracer ages, that is, the time since the water left the surface. We found low ages along the Chukchi slope in 1994, indicating a strong boundary current. After a change in atmospheric conditions, the ages along the slope increased, indicating a different pathway of the Atlantic Water in 2015. Also in 2015, the Canada Basin and the Makarov Basin were disconnected. Our tracer ages agree well with ages derived using different methods and tracers. However, we only require one tracer for the tracer age, enlarging the available data coverage. As climate change continues, it will affect atmospheric conditions and, in turn, the movement of Atlantic Water in the Arctic Ocean. We show that tracer ages can identify these changes in the Atlantic Water pathways. Key Points: Atlantic Water tracer ages under positive Arctic Oscillation are very low near Chukchi Shelf due to coherent boundary currentSF6 tracer ages show a discontinuity in Atlantic Water inflow between the Makarov and Canada Basin during mixed Arctic OscillationTracer ages are applicable to identify pathway changes in the advective Arctic Ocean [ABSTRACT FROM AUTHOR]

Published

2024

11. Vertical Carbon Export During a Phytoplankton Bloom in the Chukchi Sea: Physical Setting and Frontal Subduction.

Author

Pickart, Robert S., Spall, Michael A., Bahr, Frank, Lago, Loreley, Lin, Peigen, Pacini, Astrid, Mills, Matthew, Huang, Jie, Arrigo, Kevin R., van Dijken, Gert, McRaven, Leah T., and Roberts, Steven

Abstract

In order to quantify pelagic‐benthic coupling on high‐latitude shelves, it is imperative to identify the different physical mechanisms by which phytoplankton are exported to the sediments. In June–July 2023, a field program documented the evolution of an under‐ice phytoplankton bloom on the northeast Chukchi shelf. Here, we use in situ data from the cruise, a simple numerical model, historical water column data, and ocean reanalysis fields to characterize the physical setting and describe the dynamically driven vertical export of chlorophyll associated with the bloom. A water mass front separating cold, high‐nutrient winter water in the north and warmer summer waters to the south—roughly coincident with the ice edge—supported a baroclinic jet which is part of the Central Channel flow branch that veers eastward toward Barrow Canyon. A plume of high chlorophyll fluorescence extending from the near‐surface bloom in the winter water downwards along the front was measured throughout the cruise. Using a passive tracer to represent phytoplankton in the model, it was demonstrated that the plume is the result of subduction due to baroclinic instability of the frontal jet. This process, in concert with the gravitational sinking, pumps the chlorophyll downwards an order of magnitude faster than gravitational sinking alone. Particle tracking using the ocean reanalysis fields reveals that a substantial portion of the chlorophyll away from the front is advected off of the northeast Chukchi shelf before reaching the bottom. This highlights the importance of the frontal subduction process for delivering carbon to the sea floor. Plain Language Summary: The Chukchi Sea shelf north of Bering Strait is known to experience some of the largest phytoplankton blooms in the Arctic Ocean. In 2023, a field program was carried out to quantify aspects of the early summer bloom, with an emphasis on characterizing how the phytoplankton biomass from the bloom is exported to the sea floor. A large bloom was measured under the pack ice in very cold, high‐nutrient water, just north of warmer, ice‐free waters. The front separating the warm and cold waters supported a current flowing eastward, which is one of the main flow pathways on the Chukchi shelf. A plume of high chlorophyll fluorescence extending from the near‐surface bloom downwards along the front was measured throughout the cruise. We demonstrate that this vertical pumping was due to a dynamical process associated with the current which resulted in much faster downward export of phytoplankton than gravitational sinking alone. Tracking the fate of particles on the northeast Chukchi shelf using an ocean simulation revealed that much of the phytoplankton biomass away from the front is carried off the shelf before reaching the bottom. This highlights the importance of the frontal process for delivering chlorophyll to the sea floor. Key Points: An under‐ice phytoplankton bloom developed during June–July in the northeast Chukchi Sea within the Central Channel flow branchA plume of chlorophyll fluorescence extending downwards from the bloom along the current's water mass front was continually presentA simple numerical model demonstrates that the plume is the result of baroclinic instability of the frontal jet [ABSTRACT FROM AUTHOR]

Published

2024

12. Neogene Hydrothermal Fe‐ and Mn‐Oxide Mineralization of Paleozoic Continental Rocks, Amerasia Basin, Arctic Ocean.

Author

Hein, James R., Mizell, Kira, and Gartman, Amy

Abstract

Rocks dredged from water depths of 1,605, 2,500, 3,300, and 3,400 m in the Arctic Ocean included Paleozoic continental rocks pervasively mineralized during the Neogene by hydrothermal Fe and Mn oxides. Samples were recovered in three dredge hauls from the Chukchi Borderland and one from Mendeleev Ridge north of Alaska and eastern Siberia, respectively. Many of the rocks were so pervasively altered that the protolith could not be identified, while others had volcanic, plutonic, and metamorphic protoliths. The mineralized rocks were cemented and partly to wholly replaced by the hydrothermal oxides. The Amerasia Basin, where the Chukchi Borderland and Mendeleev Ridge occur, supports a series of faults and fractures that serve as major zones of crustal weakness. We propose that the stratabound hydrothermal deposits formed through the flux of hydrothermal fluids along Paleozoic and Mesozoic faults related to block faulting along a rifted margin during minor episodes of Neogene tectonism and were later exposed at the seafloor through slumping or other gravity processes. Tectonically driven hydrothermal circulation most likely facilitated the pervasive mineralization along fault surfaces via frictional heating, hydrofracturing brecciation, and low‐ to moderate temperature Fe‐ and Mn‐rich hydrothermal fluids, which mineralized the crushed, altered, and brecciated rocks. Plain Language Summary: In this paper, we describe a previously unknown style of marine mineral formation in the Arctic Ocean. We found that these minerals formed in the recent geologic past, approximately 8–4 million years ago, which was a surprise since no hydrothermal activity was known to occur in this region of the Arctic Ocean during this time period. Hydrothermal activity is the heating of seawater through various interactions within the earth. Here we propose that these minerals formed along seafloor faults and were later variably exposed at the seafloor. The unique style of formation for these minerals is also reflected in their mineralogy and element composition relative to other types of marine minerals found in this region. This work increases our understanding of the ways in which marine minerals may be formed, as well as the geologic processes occurring in the Arctic Ocean in the recent geological past. Key Points: First description of unique stratabound hydrothermal Fe‐ and Mn‐oxide deposits in the Amerasia Basin in the Arctic OceanThe Amerasia Basin is not known to have had a Cenozoic magmatic heat sourceWe propose that hydrothermal circulation was driven by tectonism; deposits formed along faults and exposed at the seafloor using gravity processes [ABSTRACT FROM AUTHOR]

Published

2024

13. Arctic and Southern Ocean polar sea level maps and along-tracks from multi-mission satellite altimetry from 2011 to 2021.

Author

Veillard, Pierre, Prandi, Pierre, Pujol, Marie-Isabelle, Daguzé, Jean-Alexis, Piras, Fanny, Dibarboure, Gérald, and Faugère, Yannice

Subjects

ARCTIC oscillation, ATMOSPHERIC circulation, ATMOSPHERIC tides, SOUTHERN oscillation, OCEAN

Abstract

Polar sea surface height observation by radar altimeters requires missions with high-latitude orbit and specific processing to observe the sea-ice-covered region within fractures in the ice. Here, we combine sea surface height estimates from different radar satellites over the ice-free and ice-covered polar oceans to create cross-calibrated along-tracks and gridded products over the Arctic Ocean (2011-2021) and the Southern Ocean (2013-2021). The sea surface height from our regional polar products is in great agreement with tide gauges and bottom pressure recorders at monthly timescales in seasonally to year-round icecovered regions. Thanks to the use of several missions and the mapping strategy, our multi-mission products have a greater resolution than monomission products. Part of the sea level variability of the Arctic Ocean product is related to the Arctic Oscillation atmospheric circulation. At long term, the Arctic altimetry sea level is coherent with in-situ steric height evolution in the Beaufort gyre, and negative sea level trends over the 10-year period are observed in the East Siberian slope region, which may be related to the local freshwater decrease observed by other studies. Our regional polar sea level products are limited by current understanding of the sea-ice lead measurements, and homogenization of these polar products with global sea level products needs to be tackled. [ABSTRACT FROM AUTHOR]

Published

2024

14. Projected changes to Arctic shipping routes after stratospheric aerosol deployment in the ARISE-SAI scenarios.

Author

Morrison, Ariel L., Pathak, Debanjali, Barnes, Elizabeth A., and Hurrell, James W.

Subjects

SEA ice, CLIMATE change, OCEAN temperature, AEROSOLS

Abstract

Introduction: Rapid reductions in Arctic sea ice in response to warming have led to increased interest in using the Arctic Ocean for commercial shipping. As the world warms, however, different strategies are being considered to stabilize or reduce surface temperatures in order to prevent critical climate change impacts. One such strategy is stratospheric aerosol injection (SAI), a form of solar climate intervention. Projected changes to Arctic sea ice under SAI with specific regards to shipping have not yet been assessed. Methods: We compare output from two SAI simulations that have different global mean temperature targets with a non-SAI control simulation to provide the first assessment of Arctic Ocean navigability under potential SAI scenarios. Results: We find that sea ice concentration and thickness quickly stabilize or increase after SAI deployment. When sea ice thickness stabilizes in response to SAI, the number of days when the Arctic Ocean is navigable remains fairly constant, but increasing sea ice thickness leads to reduced navigability compared to the non-SAI simulation. From 2035-2069, both the Northwest Passage and Northern Sea Route are accessible from July-November in all three simulations, but there are no navigable routes under either SAI scenario from April-June. When the Arctic is navigable, it can take 2-12 days longer to cross the Arctic Ocean in the SAI simulations than in the non-SAI control simulation, and there are large year-to-year variations in travel time. Discussion: Overall, Arctic shipping may take longer and be more difficult in an SAI vs a non-SAI world because of relatively thicker sea ice, but the degree to which Arctic shipping may change in response to SAI is dependent on the particular climate intervention strategy. [ABSTRACT FROM AUTHOR]

Published

2024

15. Contribution of Surface Waves to Sea Surface Temperatures in the Arctic Ocean.

Author

Wei, Meng, Shao, Weizeng, Shen, Wei, Hu, Yuyi, Zhang, Yu, and Zuo, Juncheng

Abstract

The aim of our study was to examine the contribution of surface waves from WAVEWATCH-III (WW3) to the variation in sea surface temperature (SST) in the Arctic Ocean. The simulated significant wave height (SWH) were validated against the products from Haiyang-2B (HY-2B) in 2021, obtaining a root mean squared error (RMSE) of 0.45 with a correlation of 0.96 and scatter index of 0.18. The wave-induced effects, i.e., wave breaking and mixing induced by nonbearing waves resulting in changes in radiation stress and Stokes drift, were calculated from WW3, ERA-5 wind, SST, and salinity data from the National Centers for Environmental Prediction and were taken as forcing fields in the Stony Brook Parallel Ocean Model. The results showed that an RMSE of 0.81 °C with wave-induced effects was less than the RMSE of 1.11 °C achieved without the wave term compared with the simulated SST with the measurements from Argos. Considering the four wave effects and sea ice freezing, the SST in the Arctic Ocean decreased by up to 1 °C in winter. Regression analysis revealed that the SWH was linear in SST (values without subtraction of waves) in summer and autumn, but this behavior was not observed in spring or winter due to the presence of sea ice. The interannual variation also presented a negative relationship between the difference in SST and SWH. [ABSTRACT FROM AUTHOR]

Published

2024

16. A Lagrangian Model‐Based Analysis of Protist Plankton Variability and Its Impact on Organic Matter Dynamics Along Transit Pathways Through the Fram Strait.

Author

Lampe, Vanessa, Hunter, Aidan, Ward, Ben Andrew, Nöthig, Eva‐Maria, Engel, Anja, Ellingsen, Ingrid Helene, and Schartau, Markus

Subjects

PLANKTON populations, ARCTIC climate, WATER masses, BIOGEOCHEMICAL cycles, REMOTE sensing

Abstract

The Arctic Ocean is characterized by substantial seasonal and inter‐annual variability, of which the sources and impacts are not yet fully understood. Here, we analyze how much of the variability found in in situ observations of biogeochemical and ecological variables collected at the Long‐Term Ecological Research Observatory HAUSGARTEN can be explained by differences in the physical conditions in the water masses passing through the Fram Strait (FS). Employing a size‐based plankton ecosystem model with nine distinct size classes of protist phyto‐ and zooplankton, we simulate standing stocks and fluxes within the nutrient, phytoplankton, zooplankton, and detritus pools in water parcels that follow trajectories tracing the opposing East‐Greenland and West‐Spitsbergen currents through the FS. Our model results agree with in situ observations of biogeochemical tracers, plankton size measurements, climatological data, and remote sensing observations. They show distinct temporal developments in plankton size composition, growth, and export in trajectory ensembles, highlighting how variable physical conditions affect the communities' specific growth histories. Our study indicates that 10%–72% of the variability in upper water column tracer concentrations observed in the FS can be attributed to differences in water parcel trajectories. The maxima of net primary production and vertical export along the trajectories occurred in some (spatial and temporal) distance upstream of the sites of in situ sampling. This study shows that Lagrangian modeling helps clarify complex biogeochemical‐ecological relationships in highly dynamic systems such as the FS, which is urgently needed to understand the role of climate change in the Arctic carbon cycle. Plain Language Summary: To study sources of biological and chemical variability in the Fram Strait (FS) (Arctic Ocean), this study uses a model that follows water parcels as they move along the currents and simulates the growth of plankton populations, their influence on nutrient concentrations and the production of dead, dissolved, and decaying organic matter. By simulating many different pathways, the model estimates how variability in the environmental conditions along those pathways contributes to the variability of the plankton ecosystem in the upper water column. When compared to real data measured from ships and observed by satellites, we find that the model successfully reproduces changes in the plankton size structure and estimates productivity and export close to observations from the region. Our study finds that a substantial portion (10%–72%) of the observed variability in biogeochemical tracers can be explained by differences in the origins and pathways of water parcels. Nonetheless, a large amount of variability remains unexplained, indicating the need for further research to better understand essential processes. This research helps us understand the sources of variability in the FS and make better predictions about elemental cycling, productivity and export, which is especially important in the face of climate change. Key Points: Local variability in tracer concentrations in Fram Strait (FS)'s upper 100 m is linked to differences in water parcel trajectoriesTrajectories differ in their origin and timing of passage, leading to differences in plankton size structure, growth, and exportAt the time of in situ observations in the FS, the maxima in net primary production and vertical export have already occurred [ABSTRACT FROM AUTHOR]

Published

2024

17. Sensitivity of Simulated Arctic Ocean Salinity and Strait Transport to Interannually Variable Hydrologic Model Based Runoff.

Author

Weiss‐Gibbons, Tahya, Tefs, Andrew, Hu, Xianmin, Stadnyk, Tricia, and Myers, Paul G.

Subjects

SEAWATER salinity, ARCTIC climate, HYDROLOGIC models, RUNOFF models, SEAWATER

Abstract

As the Arctic warms at an increased rate compared to the rest of the globe, freshwater runoff has been shown to be increasing into the Arctic Ocean. The effects of this contemporary increase in riverine freshwater into the Arctic Ocean are estimated from ocean model simulations, using two runoff data sets. One runoff data set is based on older climatological data, which has no inter‐annual variability after 2007 and as such does not represent the observed increases in river runoff into the Arctic. The other data set comes from a hydrological model developed for the Arctic drainage basin, which includes contemporary changes in the climate. At the Pan‐Arctic scale this new data set represents an approximately 11% increase in runoff, compared with the older climatological data. Comparing two ocean model runs forced with the different runoff data sets, overall changes in different freshwater markers across the basin were found to be between 5% and 10%, depending on the regions. The strongest increases were seen from the Siberian rivers, which in turn caused the strongest freshening in the Eastern Arctic. As the surface waters of the Arctic Ocean are sensitive to runoff, incorporating hydrological model data can help to better understand current changes and potential future impacts from increased runoff with climate change. Plain Language Summary: Climate change increases freshwater supply to the Arctic. This study looks at understanding the impacts of this increased riverine water into the Arctic Ocean using a state of the art regional ocean model. Two runoff forcing data sets are used, one data set which only extends to 2007 and thus does not include the recently observed runoff increases due to climate change, and a newer data set which extends up to present day and as such represents contemporary increases in the river runoff into the Arctic. Comparing two simulations forced by the two runoff datasets highlights the effects of river runoff changes on the Arctic Ocean. We find the Arctic surface waters freshen by 5%–10% over 2007–2018, depending on the metric and region considered. Much of this increased freshwater found is driven by the major Siberian rivers. This primarily affects the Eastern Arctic. Our work shows that recently observed increases in Arctic river runoff are likely impacting surface Arctic waters as well as waters transported to lower latitudes. Key Points: Pan‐Arctic river runoff increased by 11% over 2002–2019 according to hydrological model outputIn ocean model simulations this dataset gave a subsequent surface freshening of 5%–10%, as compared with classical runoff climatologySiberian rivers dominate runoff and are the main source of differences, enhancing export through Fram and Davis Straits, as observed [ABSTRACT FROM AUTHOR]

Published

2024

18. Impact of ship noise on the underwater soundscape of Eclipse Sound in the northeastern Canadian Arctic

Author

Jones, Joshua M, Westdal, Kristin H, Ootoowak, Alexander J, Wiggins, Sean M, and Hildebrand, John A

Subjects

Maritime Engineering, Engineering, Ambient sound, Arctic Ocean, Icebreaker, Ship noise, Soundscape, Marine Biology & Hydrobiology

Abstract

Eclipse Sound, in the northeastern Canadian Arctic, has experienced a substantial increase in ship traffic due to growing tourism and industrial development in the region. This study aims to describe the natural soundscape as well as to assess the noise levels associated with shipping. Underwater sound recordings were collected at two locations: Eastern Eclipse Sound (72° 43.730 N, 76° 13.519 W, 670 m) leading to Baffin Bay, and Milne Inlet (72° 15.260 N, 80° 34.205 W, 313 m) situated near the southwest end of Eclipse Sound. To capture the dynamic nature of the soundscape, the data from these two locations were divided into three seasons: late spring, summer, and early fall. These periods were selected to account for the changing contribution of sea ice to the soundscape during the sea ice break-up, two months of open water, and the sea ice freeze-up. By analyzing ship tracks and underwater acoustic recordings, we identified patterns of ship traffic and estimated underwater noise levels due to ships. Noise emitted by ships is quantified by vessel type, including three cargo ship types, passenger ships, pleasure craft, and icebreakers. Individual ship transits through the region introduce transient noise at frequencies from 20 kHz, with durations lasting from a few minutes to >6 h. The impact of ship noise on the soundscape is significant, resulting in increases in sound levels by 15 to >30 dB when ships are within 10 km and measurable ship noise below 200 Hz at distances of >50 km.

Published

2023

19. Ecosystem structure and function of the North Water Polynya

Author

Andrea Bryndum-Buchholz, Jennifer L. Herbig, Gérald Darnis, Maxime Geoffroy, and Tyler D. Eddy

Subjects

North Water Polynya, food web, ecopath, ecosystem modelling, Arctic Ocean, Environmental sciences, GE1-350, Environmental engineering, TA170-171

Abstract

The North Water Polynya is one of the most productive Arctic regions on Earth, sustaining the world's northernmost Inuit communities for millennia. The polynya is a large and persistent region of open water surrounded by sea ice and exhibits high primary productivity, is a biodiversity hotspot, and is a key habitat and migration corridor for Arctic species. Many aspects of the ecosystem structure and the role of resident species in the North Water Polynya remain uncertain. To shed light on these, we developed the first representation of the North Water Polynya food web using the Ecopath modelling framework. Modelled trophic flows indicated that pelagic and benthic communities were primarily connected by Age 1+ Arctic cod (Boreogadus saida), walrus (Odobenus rosmarus), and ringed seal (Pusa hispida). Large copepods, Age 1+ Arctic cod, and bivalves were key prey species. Overall productivity in the North Water Polynya was higher compared to Western Baffin Bay and Western Greenland, corroborating expectations of relatively high productivity within the polynya. This model provides a baseline description of the North Water Polynya ecosystem structure and function prior to future climate-driven food web changes and the emergence of large-scale commercial fisheries.

Published

2024

20. Breaks in the Arctic ice cover: from observations to predictions

Author

A. A. Ershova, L. N. Dyment, and T. A. Alekseeva

Subjects

sea ice discontinuities, ice cover deformation, satellite images, automatic identification of leads, navigation in ice, arctic ocean, Science

Abstract

Breaks (ruptures) and cracks is the distinguishing feature of any ice cover in the Arctic seas during the cold season and in the whole Arctic Basin throughout a year. The formation of them is a consequence of macro-deformation of the ice thickness. Investigating of the ice breaking in the Arctic begins with single visual observations during the ice aerial surveys in the 1940s and continues till nowadays using regular information from artificial Earth satellites. Processing of big volumes of satellite data and creating climatological datasets on breaks became possible owing to the development of algorithms for automatic identification of the ice breaks in images. Interpretation of the satellite images is based on the fundamental difference between physical properties of breaks and the surrounding consolidated ice. Algorithms for automatic recognition of ruptures using satellite data obtained in different wavelength ranges, including the use of artificial intelligence, are currently being developed. The main characteristics of breaks which are usually analyzed are as follows: the summarized area of them and its ratio to the total area of the ice field, the mean and maximum widths as well as the total length. The temporal and spatial variability of these characteristics is also considered. Such information is needed for solving problems of improving models of ice cover dynamics and modeling the interaction between the ocean and the atmosphere at high latitudes. A specific feature of publications of the Russian authors on this topic is the practical use of the results obtained for hydrometeorological support of navigation in ice. For the navigation purposes, the dominant orientation of the ruptures on the way of ships is of greatest importance. Operational and prognostic information about the orientation and extent of ruptures, including distribution of them in an ice field are the key data for choosing the optimal sailing route in the Arctic.

Published

2024

21. Changes in area fraction of sediment-laden sea ice in the Arctic Ocean during 2000 to 2021.

Author

Xie, Yuanyang, Liu, Tingting, Li, Na, and Lei, Ruibo

Abstract

Sediment-laden sea ice plays an important role in Arctic sediment transport and biogeochemical cycles, as well as the shortwave radiation budget and melt onset of ice surface. However, at present, there is a lack of efficient observation approach from both space and in situ for the coverage of Arctic sediment-laden sea ice. Thus, both spatial distribution and long-term changes in area fraction of such ice floes are still unclear. This study proposes a new classification method to extract Arctic sediment-laden sea ice on the basic of the difference in spectral characteristics between sediment-laden sea ice and clean sea ice in the visible band using the MOD09A1 data with the resolution of 500 m, and obtains its area fraction over the pan Arctic Ocean during 2000–2021. Compared with Landsat-8 true color verification images with a resolution of 30 m, the overall accuracy of our classification method is 92.3%, and the Kappa coefficient is 0.84. The impact of clouds on the results of recognition and spatiotemporal changes of sediment-laden sea ice is relatively small from June to July, compared to that in May or August. Spatially, sediment-laden sea ice mostly appears over the marginal seas of the Arctic Ocean, especially the continental shelf of Chukchi Sea and the Siberian seas. Associated with the retreat of Arctic sea ice extent, the total area of sediment-laden sea ice in June–July also shows a significant decreasing trend of 8.99 × 104 km2 per year. The occurrence of sediment-laden sea ice over the Arctic Ocean in June–July leads to the reduce of surface albedo over the ice-covered ocean by 14.1%. This study will help thoroughly understanding of the role of sediment-laden sea ice in the evolution of Arctic climate system and marine ecological environment, as well as the heat budget and mass balance of sea ice itself. [ABSTRACT FROM AUTHOR]

Published

2024

22. International Ocean Discovery Program Expedition 403 Preliminary Report: Eastern Fram Strait Paleo-Archive: 4 June-2 August 2024.

Author

Lucchi, Renata Giulia, St. John, Kristen E. K., and Ronge, Thomas A.

Subjects

SEA ice, CLIMATE change, GLOBAL warming

Abstract

The North Atlantic and Arctic Oceans are unquestionably major players in the climatic evolution of the Northern Hemisphere and in the history of the meridional overturning circulation of the Atlantic Ocean. The establishment of the modern North Atlantic Water (NAW) transporting heat, salt, and moisture to the Northern Hemisphere has been indicated as one of the main forcing mechanisms for the onset of Northern Hemisphere glaciation. NAW controls the extent and dynamics of circum-Arctic and circum-North Atlantic ice sheets and sea ice in addition to deep water and brine production. How the ocean system and cryosphere worked during past warmer intervals of high insulation and/or high atmospheric CO2 content is still largely unknown and debated. The required information can only be attained by offshore scientific drilling in highresolution continuous expanded sedimentary sequences identified on the western continental margin of Svalbard (and eastern side of the Fram Strait) along the main pathway and northern penetration of the NAW flowing into the Arctic Ocean. The area around Svalbard is very sensitive to climatic variability and can be considered a sentinel of climate change. Furthermore, the reconstruction of the dynamic history of the marine-based paleo-Svalbard-Barents Sea Ice Sheet is important because it is considered the best available analog to the modern, marine-based West Antarctic Ice Sheet, for which the loss of stability is presently the major uncertainty in projecting future global sea level rise in response to the present global climate warming. [ABSTRACT FROM AUTHOR]

Published

2024

23. Destination 90°N: dimensions and geographies of tourism at the North Pole.

Author

Varnajot, Alix and Lépy, Élise

Subjects

CLIMATE change, TOURISM, OCEAN, TOURISTS, TRAVELERS

Abstract

Despite its extreme remoteness, the geographic North Pole is attracting more tourists than ever before, bringing increasing numbers of people and ships to the Arctic Ocean. This growth is regarded as potentially damaging to the Arctic environment, especially combined with the effects of climate change on the sea ice. Yet, to understand and anticipate future changes related to increasing tourism at the North Pole (and the Arctic Ocean), it is critical to both assess the current situation of tourism and to anticipate the future of tourism in the region in light of climate change projections. Therefore, this article explores the dimensions and geographies of tourism development at the North Pole, and more generally in the Arctic Ocean, in terms of modes of tourism, itineraries, and estimated numbers of tourists. To do so, we examine three main forms of tourism taking place in the region, namely icebreaker cruises, frontier travelers venturing on the sea ice, and ice camps. The article also aims to discuss the future of tourism in the region in light of estimated climate change impacts on the sea ice, in order to better plan and adapt to a future seasonally ice-free Arctic Ocean. [ABSTRACT FROM AUTHOR]

Published

2024

24. Simulated Impact of Time‐Varying River Runoff and Greenland Freshwater Discharge on Sea Level Variability in the Beaufort Gyre Over 2005–2018.

Author

Tajouri, S., Llovel, W., Sévellec, F., Molines, J.‐M., Mathiot, P., Penduff, T., and Leroux, S.

Subjects

SEA ice, ADVECTION, FRESH water, RUNOFF, OCEAN

Abstract

Global mean sea level has been rising at a rate of 3.25 ± 0.4 mm yr−1 over 1993–2018. Yet several regions are increasing at a much faster rate, such as the Beaufort Gyre in the Arctic Ocean at a rate of 9.3 ± 7.0 mm yr−1 over 2003–2014. At interannual to decadal time scales, the Beaufort Gyre sea level is controlled by salinity changes due to sea ice melt and wind‐driven lateral Ekman convergence–divergence of freshwater. This study uses recent Greenland discharge and river runoff estimates to isolate and quantify the sea level response to freshwater fluxes variability over the period 1980–2018. It relies on sensitivity experiments based on a global ocean model including sea‐ice and icebergs. These sensitivity experiments only differ by the freshwater fluxes temporal variability of Greenland and global rivers which are either seasonal climatologies or fully time varying, revealing the individual and combined impact of these freshwater sources fluctuations. Fully varying Greenland discharge and river runoff produce an opposite impact on sea level trends over 2005–2018 in the Beaufort Gyre region, the former driving an increase, while the latter, a decrease. Their combined impact leads to a fairly weak sea level trend. The sea level response is primarily driven by salinity variations in the upper 300 m, which are mainly caused by salinity advection involving complex compensations between passive, active, and nonlinear advection. This study shows that including the temporal variability of freshwater fluxes in forced global ocean models results in a better representation of regional sea level change. Plain Language Summary: Sea level is rising globally but not at the same rate everywhere. In the Arctic Ocean, the Beaufort Gyre sea level has been increasing at a fast rate of 9.3 ± 7.0 mm yr−1 over 2003–2014. At long time scales, the Beaufort Gyre sea level change is controlled by salinity, which depends mainly on continental freshwater runoff—particularly high in this region—and sea ice melt. This study uses recent estimates of Greenland discharge and river runoff in a global ocean model. The aim is to isolate and quantify the sea level response of the Beaufort Gyre to freshwater fluxes variability. We compare numerical simulations where Greenland discharge and river runoff are fully varying or set to a repeated seasonal cycle to reveal the individual and combined impacts of the variability of these freshwater sources on regional sea level. Both Greenland discharge and global river runoff impact remotely the Beaufort Gyre sea level. They induce salinity variations in the upper 300 m of the gyre through salinity advection. This study highlights the importance of the variability of continental freshwater fluxes in models in order to better represent regional sea level variability. Key Points: Greenland discharge and river runoff variability contribute to sea level rise and fall in the Beaufort GyreThe positive impact of Greenland is greater than the negative impact of rivers in the 0–78‐m range, and vice versa in the 78–300‐m rangeSea level change in the sensitivity experiments is mostly halosteric with salinity changes mainly controlled by advection [ABSTRACT FROM AUTHOR]

Published

2024

25. Two Decades of Arctic Sea-Ice Thickness from Satellite Altimeters: Retrieval Approaches and Record of Changes (2003–2023).

Author

Kacimi, Sahra and Kwok, Ron

Subjects

*SNOW accumulation, *PRODUCTION quantity, *ICE, *ALTIMETERS, *LIDAR

Abstract

There now exists two decades of basin-wide coverage of Arctic sea ice from three dedicated polar-orbiting altimetry missions (ICESat, CryoSat-2, and ICESat-2) launched by NASA and ESA. Here, we review our retrieval approaches and discuss the composite record of Arctic ice thickness (2003–2023) after appending two more years (2022–2023) to our earlier records. The present availability of five years of snow depth estimates—from differencing lidar (ICESat-2) and radar (CryoSat-2) freeboards—have benefited from the concurrent operation of two altimetry missions. Broadly, the dramatic volume loss (5500 km3) and Arctic-wide thinning (0.6 m) captured by ICESat (2003–2009), primarily due to the decline in old ice coverage between 2003 and 2007, has slowed. In the central Arctic, away from the coasts, the CryoSat-2 and shorter ICESat-2 records show near-negligible thickness trends since 2007, where the winter and fall ice thicknesses now hover around 2 m and 1.3 m, from a peak of 3.6 m and 2.7 m in 1980. Ice volume production has doubled between the fall and winter with the faster-growing seasonal ice cover occupying more than half of the Arctic Ocean at the end of summer. Seasonal ice behavior dominates the Arctic Sea ice's interannual thickness and volume signatures. [ABSTRACT FROM AUTHOR]

Published

2024

26. The Greenland–Scotland Ridge in a Changing Ocean: Time to Act?

Author

Pampoulie, Christophe, Brix, Saskia, and Randhawa, Haseeb S.

Subjects

*MARINE biodiversity conservation, *MARINE resource management, *ARCTIC climate, *FRONTS (Meteorology), *SEAMOUNTS, *MARINE resources conservation, *TUNDRAS

Abstract

ABSTRACT The Greenland–Scotland Ridge is a submarine mountain that rises up to 500 m below the sea surface and extends from the east coast of Greenland to the continental shelf of Iceland and across the Faroe Islands to Scotland. The ridge not only separates deeper ocean basins on either side, that is, the North Atlantic and Arctic oceans, but also forms a geomorphological barrier between the cold arctic water masses of the Nordic Seas and the comparably contrastingly warmer water of the North Atlantic Ocean. It is therefore situated at a strategic geographical position in relation to the effect of climate change in the Arctic region. Both the Arctic and the Atlantic subpolar ecosystems are facing each other at the ridge, creating oceanic fronts in the Denmark Strait and in the Iceland–Faroe ridge alike. This ridge in the subarctic area forms the southern boundary of the North Atlantic Gateway to the Arctic Ocean, affecting exchanges of oceanic currents and of marine organisms between the two main ecosystems in the Nordic polar region. For example, the appearance of natural invasive species such as the Atlantic mackerel in this region mainly occurred along the ridge, with arrival through the Scotland–Faroe Islands mount with subsequent waves of colonization which eventually reached the southern tip of Greenland. With the increasing impacts of climate change, such natural colonization through the ridge is likely to happen more frequently and affect regional ecosystems. Yet, the human resources and the economy of the local nations on the ridge are rather limited compared to neighboring countries. With a total of less than half a million people inhabiting the area and a total ocean surface of circa 3 million km2 of continental shelf, Greenland, Iceland, the Faroe Islands, and Scotland will face critical challenges in the coming years with respect to biodiversity conservation and sustainable management of marine resources. Here is a summary of what we know, what we might expect, and an opening to potential discussions for the future of research in this region. The main objective of this paper is calling attention to much needed additional research effort on the marine environment around the Greenland–Scotland Ridge, instead of presenting a comprehensive overview of research in this area. [ABSTRACT FROM AUTHOR]

Published

2024

27. Content and Composition of Rock Debris at Lomonosov Ridge (83° N): Indication of Palaeoenvironmental Changes.

Author

Popova, E. A., Bogin, V. A., Malyshev, S. A., Filchuk, K. V., Makarov, A. S., and Kaminsky, V. D.

Subjects

*SEDIMENT sampling, *GLACIAL melting, *RESEARCH institutes, ARCTIC exploration, ANTARCTIC exploration

Abstract

The results of studying the quantitative, material, and morphometric composition of rock debris in sediments sampled by a box-corer on Lomonosov Ridge (83° N), Arctic Ocean, during the Severnyi Polyus 41 expedition of the Arctic and Antarctic Research Institute are presented. Clasts ≥ 1 cm in size were sampled from each distinguished layer according to the lithological description. The age model was created by the lithostratigraphic correlation with previously dated cores. The content of clasts on the eastern slope and summit is significantly higher than on the western slope, which is explained by the higher sedimentation rate on the western slope after the deglaciation peak. The change in the rock composition from carbonate to igneous and the increase in roundness with time indicate a higher input of Eurasian material in MIS 1. [ABSTRACT FROM AUTHOR]

Published

2024

28. Inversion of Seabed Geotechnical Properties in the Arctic Chukchi Deep Sea Basin Based on Time Domain Adaptive Search Matching Algorithm.

Author

An, Long, Xu, Chong, Xing, Junhui, Gong, Wei, Jiang, Xiaodian, Xu, Haowei, Liu, Chuang, and Yang, Boxue

Abstract

The chirp sub-bottom profiler, for its high resolution, easy accessibility and cost-effectiveness, has been widely used in acoustic detection. In this paper, the acoustic impedance and grain size compositions were obtained based on the chirp sub-bottom profiler data collected in the Chukchi Plateau area during the 11th Arctic Expedition of China. The time-domain adaptive search matching algorithm was used and validated on our established theoretical model. The misfit between the inversion result and the theoretical model is less than 0.067%. The grain size was calculated according to the empirical relationship between the acoustic impedance and the grain size of the sediment. The average acoustic impedance of sub-seafloor strata is 2.5026 × 106 kg (s m2)−1 and the average grain size (θ value) of the seafloor surface sediment is 7.1498, indicating the predominant occurrence of very fine silt sediment in the study area. Comparison of the inversion results and the laboratory measurements of nearby borehole samples shows that they are in general agreement. [ABSTRACT FROM AUTHOR]

Published

2024

29. Distribution of 137Cs specific activity in river sediments of the Barents Sea basin (Nenets Autonomous Okrug, Russian Arctic).

Author

Puchkov, Andrey, Yakovlev, Evgeny, Druzhinina, Anna, and Druzhinin, Sergey

Subjects

NUCLEAR power plant accidents, RIVER sediments, LAKE sediments, WATERSHEDS, PARTICLE size distribution

Abstract

This article focuses on the study of the distribution of 137Cs in the bottom sediments of Arctic rivers of the Barents Sea basin (using the example of the Nenets Autonomous Okrug, Russian Arctic). This research is relevant due to the poorly studied region and the significant number of radiation-hazardous facilities in the Arctic zone of Russia, both those currently in operation and those that are "nuclear heritage sites". The study of 137Cs specific activity in bottom sediments was carried out in the period from 2020 to 2023 in the rivers Chizha, Nes, Vizhas, Oma, Pechora (river delta), as well as the rivers Kolva and Usa (first and second order tributaries, respectively, of the Pechora River). A total of 199 samples were collected. In addition to 137Cs specific activity, the samples were analysed for sediment particle size distribution, organic matter content, carbonate content and ash content. The 137Cs specific activity mainly ranged from the minimum detectable specific activity to 5.4 ± 0.8 Bq·kg−1. In the Nes River basin (Kaninskaya tundra), the 137Cs content in bottom sediments reached 36.0 ± 3.2 Bq·kg−1 (in the case of lake sediments) and 22.9 ± 3.7 Bq·kg−1 (in the case of river sediments), values that are higher than those of the North-West of Russia. Considering the large area of the study area (Kaninskaya tundra, Pechora river delta, southern part of Bolshezemelskaya tundra) and the similarity of physical and chemical parameters of the studied rivers, it is possible to assume the existence of a zone of increased radionuclide content in the Nes river basin. This may be due to the runoff from the Nes River catchment area, its hydrological features, and the accumulation of 137Cs in the small fractions of bottom sediments. The results confirm the conclusions of previous soil studies in the Nes river basin. The main sources of elevated 137Cs content are global atmospheric deposition and the Chernobyl Nuclear Power Plant accident. [ABSTRACT FROM AUTHOR]

Published

2024

30. Modeling the Responses of Phytoplankton Assemblage and Biological Pump Efficiency to Environmental Changes in the Chukchi Borderland, Western Arctic Ocean.

Author

Luo, Xiaofan, Dong, Chunming, Wei, Hao, Zhao, Wei, and Nie, Hongtao

Subjects

MARINE phytoplankton, COLLOIDAL carbon, CARBON cycle, CONTINENTAL shelf, GROWING season, SEA ice

Abstract

The Chukchi Borderland, connecting the Chukchi continental shelf and the Canada Basin, has become a hotspot for studying how ecosystems respond to rapid environmental changes in the Arctic Ocean. Based on a long‐term hindcast simulation during 1998–2015 using a coupled ocean‐sea ice‐biogeochemical model, this study investigates the responses of phytoplankton assemblage and the biological carbon pump efficiency within the upper layers (0–100 m) of the Chukchi Borderland. The nitrate concentration is found to be a crucial factor controlling the total phytoplankton biomass and determining the spatiotemporal variations in the evolution pattern of phytoplankton assemblage. In the shelf break adjacent region, nitrate concentration increased after 2009, boosting phytoplankton biomass with diatoms persistently dominating. In the Canada Basin adjacent region, the westward expansion of the Beaufort Gyre after 2009 extended the influence of oligotrophic water, leading to phytoplankton miniaturization and a shift in phytoplankton assemblage evolution, from a pre‐2009 pattern that non‐diatoms at start were succeeded by diatoms, to a post‐2009 scenario that non‐diatoms dominated throughout the growing season. The biological pump efficiency evidently increased in the shelf break region after 2009, due to heightened biomass and intensified horizontal advection‐induced particulate organic carbon (POC) supply. The western Canada Basin adjacent region presented the reduced primary production and vertical POC flux. However, the deeper nitracline deepened the phytoplankton habitat, shortening POC residence time in the upper layers and enhancing the biological pump efficiency. Plain Language Summary: The responses of marine phytoplankton and the biological carbon pump efficiency to rapid changes in the Chukchi Borderland are studied through analyzing a numerical model simulation spanning 1998–2015. In the upper ocean (0–100 m depth), the nitrate concentration is found to be a crucial factor for space‐time variations of the total biomass and the dominance of phytoplankton groups. Over the continental shelf and shelf break, nitrate increased after 2009, promoting the growth of larger‐size phytoplankton (diatoms) and sustaining their dominance throughout most of the growing season. In the region near western Canada Basin, the westward expansion of the Beaufort Gyre (nitrate‐low water) favored the smaller‐size phytoplankton growth. This shift is expected to reduce the quality of ecosystem production. The biological carbon pump efficiency generally increased after 2009, indicating a faster transfer of biologically fixed carbon into deep water. In the shelf break region, this efficiency increase was due to heightened local primary production and increased horizontal transport of particulate organic carbon supply. Near the western Canada Basin, it was due to a deeper phytoplankton habitat. These results provide new perspectives for the evaluation of carbon sinks in the western Arctic Ocean. Key Points: Nitrate levels shape regional differences in annual evolution of phytoplankton assemblageOligotrophic Canada Basin water leads to phytoplankton miniaturization and assemblage evolution shifts in its expanded regionBio‐pump efficiency is promoted by increased productivity and advected particulate organic carbon over shelf break, while by deeper habitat near Canada Basin [ABSTRACT FROM AUTHOR]

Published

2024

31. Three Forcing Mechanisms of Freshwater Transport in Fram Strait.

Author

Karpouzoglou, T., De Steur, L., Smedsrud, L. H., Karcher, M., and Sumata, H.

Subjects

MERIDIONAL overturning circulation, ARCTIC oscillation, FRESH water, WIND pressure, TIME series analysis

Abstract

Fram Strait is one of the main gateways for fresh water leaving the Arctic Ocean toward the deep‐water formation regions of the North Atlantic. Monitoring transport through Fram Strait is important to quantify the impact of Arctic amplification on the hydrography in lower latitudes. We update existing time series from the moorings in the western Fram Strait and investigate the monthly and interannual variability of the liquid freshwater transport (FWT, reference salinity 34.9), volume transport and freshwater content between 2003 and 2020. We examine composites and correlations of sea‐level pressure (SLP) reanalysis, and remote‐sensing dynamic‐ocean topography (DOT) in the Arctic Ocean. We identify two remote forcing mechanisms of FWT: (a) North Pole convergence freshens the region north of Fram Strait 13–24 months before high FWT events. (b) Beaufort Gyre weakening allows spreading of fresh water to the margins of the Arctic Basin zero to 9 months before high FWT events. In addition a third mechanism occurs locally, (b) Fram Strait northerly winds confine freshwater to the Greenland shelf and drive stronger southward FWT. Additionally, we find a decreasing trend in the total volume transport, concurrent with weakening northerly winds and reducing north‐south DOT gradient across the strait. We also examined correlations between the Fram Strait time series and the Arctic Oscillation and Arctic Ocean Oscillation. Both are found to correlate positively with the total volume transport, while the Arctic Oscillation correlates negatively with FWT with 1‐year lag. Plain Language Summary: The East Greenland Current brings fresh water from the central Arctic Ocean to lower latitudes. The exported fresh water affects stratification, and can contribute to variations of the global meridional overturning circulation. In Fram Strait, between Greenland and Svalbard, the properties of this current have been systematically monitored using moored instruments. We present updated time series of freshwater transport from the moorings in the Fram Strait, and analyze their variability between 2003 and 2020. We identify three mechanisms that contribute to high freshwater transport in the Strait. (a) 13–24 months before, clockwise wind anomalies in the Eurasian Arctic drive converging current anomalies and freshen the area preconditioning fresh outflow events. (b) 0–9 months before, anticlockwise wind anomalies in the Canadian Arctic drive diverging current anomalies directing fresh water to the periphery and Fram Strait. (c) Northerly winds over the strait drive southward transport instantly. We find additionally that total volume transport in the Fram Strait decreases in relation to weakening northerlies that could be a result of a warming Greenland. Key Points: Fram Strait local northerly winds force instant southward volume and freshwater transportArctic Ocean large‐scale wind variability forces two distinguished lagged responses of freshwater content and transport in Fram StraitBetween 2004 and 2019 freshwater transport shows no trend but total volume transport of the East Greenland Current decreases by ∼0.1 SV/year [ABSTRACT FROM AUTHOR]

Published

2024

32. Quantifying Drivers of Seasonal and Interannual Variability of Dissolved Oxygen in the Canada Basin Mixed Layer.

Author

Arroyo, Ashley, Timmermans, Mary‐Louise, and DeGrandpre, Mike

Subjects

SEASONS, MIXING height (Atmospheric chemistry), OCEANIC mixing, WATER masses, SPRING, ATMOSPHERE, SEA ice

Abstract

Analysis of dissolved oxygen (O2) in the Arctic's surface ocean provides insights into gas transfer between the atmosphere‐ice‐ocean system, water mass dynamics, and biogeochemical processes. In the Arctic Ocean's Canada Basin mixed layer, higher O2 concentrations are generally observed under sea ice compared to open water regions. Annual cycles of O2 and O2 saturation, increasing from summer through spring and then sharply declining to late summer, are tightly linked to sea ice cover. The primary fluxes that influence seasonal variability of O2 are modeled and compared to Ice‐Tethered Profiler O2 observations to understand the relative role of each flux in the annual cycle. Findings suggest that sea ice melt/growth dominates seasonal variations in mixed layer O2, with minor contributions from vertical entrainment and atmospheric exchange. While the influence of biological activity on O2 variability cannot be directly assessed, indirect evidence suggests relatively minor contributions, although with significant uncertainty. Past studies show that O2 molecules are expelled from sea ice during brine rejection; sea ice cover can then inhibit air‐sea gas exchange resulting in winter mixed layers that are super‐saturated. Decreasing mixed layer O2 concentrations and saturation levels are observed during winter months between 2007 and 2019 in the Canada Basin. Only a minor portion of the decreasing trend in wintertime O2 can be attributed to decreased solubility. This suggests the O2 decline may be linked to more efficient air‐sea exchange associated with increased open water areas in the winter sea ice pack that are not necessarily detectable via satellite observations. Plain Language Summary: Dissolved oxygen (O2) is a valuable ocean property that allows us to better understand the exchange of gases between the different ocean layers, sea ice, and atmosphere, and the physical and biological processes that control its variability. Understanding how and why O2 concentrations in the Arctic Ocean mixed layer vary spatially and seasonally is crucial for interpreting its evolution over timescales of years to decades that are influenced by global warming. We use physical and thermodynamical relationships to model the main factors that influence O2 concentrations in the mixed layer of the Arctic Ocean's Canada Basin, which we compare to observations made by Ice‐Tethered Profilers. Model results indicate that seasonal variations in O2 concentrations are dominated by the effects of sea ice growth and melt. Other processes that modulate mixed layer O2, including air‐sea exchange and ocean mixing, have a lesser influence. Between 2007 and 2019, mixed‐layer O2 has decreased in winter months, which we attribute to more openings in the sea‐ice pack during wintertime in the Canada Basin. Key Points: Spatial and seasonal distributions of O2 concentrations in the Canada Basin mixed layer are linked to the seasonal evolution of sea iceModeled fluxes suggest brine rejection and meltwater dilution during sea ice melt/formation dominate seasonal variability of mixed layer O2Decreases in mixed‐layer O2 during winter (over 2007–2019) suggest outgassing, likely driven by changes in the wintertime sea ice pack [ABSTRACT FROM AUTHOR]

Published

2024

33. Arctic Freshwater Sources and Ocean Mixing Relationships Revealed With Seawater Isotopic Tracing.

Author

Kopec, Ben G., Klein, Eric S., Feldman, Gene C., Pedron, Shawn A., Bailey, Hannah, Causey, Douglas, Hubbard, Alun, Marttila, Hannu, and Welker, Jeffrey M.

Subjects

OCEANIC mixing, WATER masses, FRESH water, SEAWATER salinity, TRACERS (Chemistry), WATER vapor

Abstract

The Arctic Ocean and adjacent seas are undergoing increased freshwater influx due to enhanced glacial and sea ice melt, precipitation, and runoff. Accurate delineation of these freshwater sources is vital as they critically modulate ocean composition and circulation with widespread and varied impacts. Despite this, the delineation of freshwater sources using physical oceanographic measurements (e.g., temperature, salinity) alone is challenging and there is a requirement to improve the partitioning of ocean water masses and their mixing relationships. Here, we complement traditional oceanographic measurements with continuous surface seawater isotopic analysis (δ18O and deuterium excess) across a transect extending from coastal Alaska to Baffin Bay and the Labrador Sea conducted from the US Coast Guard Cutter Healy in Autumn 2021. We find that the diverse isotopic signatures of Arctic freshwater sources, coupled with the high freshwater proportion in these marine systems, facilitates detailed fingerprinting and partitioning. We observe the highest freshwater composition in the Beaufort Sea and Amundsen Gulf regions, with heightened freshwater content in eastern Baffin Bay adjacent to West Greenland. We apply isotopic analysis to delineate freshwater sources, revealing that in the Western Arctic freshwater inputs are dominated by meteoric water inputs—specifically the Mackenzie River—with a smaller sea ice meltwater component and in Baffin Bay the primary sources are local precipitation and glacial meltwater discharge. We demonstrate that such freshwater partitioning cannot be achieved using temperature‐salinity relationships alone, and highlight the potential of seawater isotopic tracers to assess the roles and importance of these evolving freshwater sources. Plain Language Summary: Freshwater inputs to the Arctic seas, including glacial and sea ice meltwater, precipitation, and river runoff, are increasing as the Arctic warms. The impacts of these changing freshwater influxes are varied depending on the type of freshwater source, and thus it is important to delineate and trace these different freshwater sources, which represents a significant challenge using only traditional physical oceanographic measurements (e.g., temperature, salinity). In this study, we utilize a new approach to identify and trace freshwater sources using continuous seawater isotopic measurements during a cruise extending from coastal Alaska, through the Canadian Archipelago, and across Baffin Bay and the Labrador Sea. We show that these isotopic measurements, which have been commonly used in other media (e.g., precipitation, water vapor, ice cores), hold important and distinct information about the source and mixing of different freshwater sources. We use these measurements to identify the freshwater sources (e.g., Mackenzie vs. Yukon River) contributing to ocean surface waters across the Arctic region. Key Points: Seawater isotopic measurements (δ18O, δ2H, deuterium excess) show heightened freshwater content in the Beaufort Sea and Baffin BayIsotopic observations enable freshwater source delineation not feasible from traditional physical oceanographic methodsFreshwater source delineation includes the Mackenzie and Yukon Rivers around coastal Alaska and glacial meltwater in Baffin Bay [ABSTRACT FROM AUTHOR]

Published

2024

34. Temporal Variability of Ventilation in the Eurasian Arctic Ocean.

Author

Gerke, Lennart, Arck, Yannis, and Tanhua, Toste

Subjects

VENTILATION, GLOBAL warming, OCEAN, DISSOLVED oxygen in water, MERIDIONAL overturning circulation, WATER masses

Abstract

The Arctic Ocean plays an important role in the regulation of the earth's climate system, for instance by storing large amounts of carbon dioxide within its interior. It also plays a critical role in the global thermohaline circulation, transporting water entering from the Atlantic Ocean to the interior and initializing the southward transport of deep waters. Currently, the Arctic Ocean is undergoing rapid changes due to climate warming. The resulting consequences on ventilation patterns, however, are scarce. In this study we present transient tracer (CFC‐12 and SF6) measurements, in conjunction with dissolved oxygen concentrations, to asses ventilation and circulation changes in the Eurasian Arctic Ocean over three decades (1991–2021). We constrained transit time distributions of water masses in different areas and quantified temporal variability in ventilation. Specifically, mean ages of intermediate water layers in the Eurasian Arctic Ocean were evaluated, revealing a decrease in ventilation in each of the designated areas from 2005 to 2021. This intermediate layer (250–1,500 m) is dominated by Atlantic Water entering from the Nordic Seas. We also identify a variability in ventilation during the observation period in most regions, as the data from 1991 shows mean ages comparable to those from 2021. Only in the northern Amundsen Basin, where the Arctic Ocean Boundary Current is present at intermediate depths, the ventilation in 1991 is congruent to the one in 2005, increasing thereafter until 2021. This suggests a reduced ventilation and decrease in the strength of the Boundary Current during the last 16 years. Plain Language Summary: The Eurasian Arctic Ocean, the region of the Arctic Ocean connected to the European and Asian continents, is an important pathway for recently ventilated water from the Nordic Seas. These waters are exported back to the North Atlantic following their travel through the Arctic Ocean. Ventilation describes the process of surface waters being transported into the interior ocean due to increasing density, which affects the underlying water masses. In this study we investigate how the ventilation patterns have evolved in the Eurasian Arctic Ocean over the past three decades, using transient tracer (CFC‐12 and SF6) measurements. We observed a significant change in the intermediate layer (250–1,500 m) with older waters found in measurements in 1991 and 2021 compared to 2005 and 2015. Moreover, our data suggest a slowdown in ventilation throughout the three decades in the northern Amundsen Basin, implying a decrease in the circulation time‐scale of the Arctic Ocean Boundary Current over the past 16 years. This has potentially important implications for the transport of, for example, heat, salt or oxygen from the Atlantic Ocean around the Arctic Ocean, and back. Key Points: Temporal variability of ventilation in the Eurasian Arctic Ocean during the past 30 years is estimated by observations of transient tracersWe found a slow down of the ventilation between 2005 and 2021 in the intermediate watersEvidence of multidecadal variability of ventilation in the intermediate waters of the Eurasian Arctic Ocean is present [ABSTRACT FROM AUTHOR]

Published

2024

35. Modeling pan-Arctic seasonal and interannual landfast sea ice thickness and snow depth between 1979 and 2021

Author

Zihan Wang, Jiechen Zhao, Bin Cheng, Fengming Hui, Jie Su, and Xiao Cheng

Subjects

Arctic Ocean, landfast sea ice, sea ice thickness, sea ice volume, snow depth, numerical simulation, Mathematical geography. Cartography, GA1-1776

Abstract

Landfast sea ice (LFSI) is sensitive to local climate change, making it an important component of the cryosphere system. In this study, the LFSI around the pan-Arctic domain was simulated from 1979 to 2021 using a well-validated snow and ice thermodynamic model (HIGHTSI) under the framework of the Fast Ice Prediction System (FIPS), forced by the ERA5 reanalysis. The simulation results agree well with the in-situ observations in the Canadian Arctic, with a mean error of −0.06 ± 0.29 m for ice thickness and −0.04 ± 0.12 m for snow depth. A decrease of −2.8 ± 0.4 cm/10a in thickness and −16.2 ± 1.5 km3/a in volume for the Arctic LFSI was modeled during this period. There was significant spatial variability among the different domains, with the fastest decline found in the Vilkitsky Strait. The modeled snow depth shows large interannual and spatial variations, which was confirmed by other modeling results. The spatiotemporal variations in both air temperature and precipitation are the driving factors for the multi-decadal variations in LFSI thickness. The decreasing air temperature during the 2010s aligned with a slower thickness decrease and a slight volume increase for LFSI, which agreed with the pan-Arctic sea ice pattern.

Published

2024

36. Neogene Hydrothermal Fe‐ and Mn‐Oxide Mineralization of Paleozoic Continental Rocks, Amerasia Basin, Arctic Ocean

Author

James R. Hein, Kira Mizell, and Amy Gartman

Subjects

Arctic Ocean, Amerasia Basin, deep water, hydrothermal oxide deposits, Neogene age, fault hosted, Geophysics. Cosmic physics, QC801-809, Geology, QE1-996.5

Abstract

Abstract Rocks dredged from water depths of 1,605, 2,500, 3,300, and 3,400 m in the Arctic Ocean included Paleozoic continental rocks pervasively mineralized during the Neogene by hydrothermal Fe and Mn oxides. Samples were recovered in three dredge hauls from the Chukchi Borderland and one from Mendeleev Ridge north of Alaska and eastern Siberia, respectively. Many of the rocks were so pervasively altered that the protolith could not be identified, while others had volcanic, plutonic, and metamorphic protoliths. The mineralized rocks were cemented and partly to wholly replaced by the hydrothermal oxides. The Amerasia Basin, where the Chukchi Borderland and Mendeleev Ridge occur, supports a series of faults and fractures that serve as major zones of crustal weakness. We propose that the stratabound hydrothermal deposits formed through the flux of hydrothermal fluids along Paleozoic and Mesozoic faults related to block faulting along a rifted margin during minor episodes of Neogene tectonism and were later exposed at the seafloor through slumping or other gravity processes. Tectonically driven hydrothermal circulation most likely facilitated the pervasive mineralization along fault surfaces via frictional heating, hydrofracturing brecciation, and low‐ to moderate temperature Fe‐ and Mn‐rich hydrothermal fluids, which mineralized the crushed, altered, and brecciated rocks.

Published

2024

37. Nitrous oxide dynamics in the Kara Sea, Arctic Ocean

Author

Sofia Muller, François Fripiat, Samuel L. Jaccard, Leandro Ponsoni, Jens A. Hölemann, Alfredo Martínez-García, and Bruno Delille

Subjects

nitrous oxide, N2O flux, air-sea exchange, Kara Sea, arctic ocean, nitrification, Science, General. Including nature conservation, geographical distribution, QH1-199.5

Abstract

Previous studies have reported an accumulation of nitrous oxide (N2O) on shallow continental shelves of the western Arctic Ocean. In this study, we sampled seawater profiles for N2O measurements in the eastern Arctic shelves, in the North Kara Sea, in the context of the Arctic Century Expedition. Despite some variability in the vertical distribution, we typically observe an accumulation of N2O in shelf bottom waters, which correlates with a fixed nitrogen (N) deficit. Longer residence times on the shelf promote greater N2O enrichment and a larger fixed N deficit. These observations point towards N2O production at depth, linked to benthic denitrification processes that are intensified on productive shelve areas. However, in surface waters, physical processes – i.e. temperature-dependent solubility and air-sea exchange – emerge as the main factor controlling N2O concentrations. We observe low saturations of 80% at the surface of open ocean stations influenced by water that has previously flowed beneath sea ice. Arctic surface water becomes undersaturated due to cooling and remains undersaturated due to limited air-sea exchange. River supply does not exert a discernable influence on N2O concentrations of the studied area. This study reveals the potential of the Arctic Siberian shelves as a sink of atmospheric N2O during the summer.

Published

2024

38. Microplastic fate in Arctic coastal waters: accumulation hotspots and role of rivers in Svalbard

Author

Svetlana Pakhomova, Anfisa Berezina, Igor Zhdanov, and Evgeniy Yakushev

Subjects

plastic pollution, Arctic Ocean, Arctic rivers, hydrodynamics, fjords, Science, General. Including nature conservation, geographical distribution, QH1-199.5

Abstract

Little is known about the role of remote and sparsely populated Arctic coastal zones in the microplastic cycle. Distribution of microplastics was studied in the Svalbard fjords in June – July 2022 with the main goal of assessing rivers’ role in the fate of microplastic in Arctic coastal waters. Surface microplastics (0 – 20 cm depth, 500 – 5000 µm size) were sampled with a neuston net in triplicate per study site in parallel with sampling of subsurface microplastics with a pump system (1.5 m depth, 100 – 5000 µm size). The central part of Isfjorden and its several branches covering populated and unpopulated fjords were studied; the sampling was conducted during an intense riverine discharge in all studied sites. Maximum abundance of surface microplastics (71,400 items/km2 or 0.19 iterms/m3, 0.19 mg/m3) was found along the river plume border in the middle of populated Adventfjorden indicating importance of both local sources and surface hydrodynamics in the formation of microplastics accumulation hotspots. All other unpopulated fjords were free of the floating on the sea surface microplastics as river discharge prevented transport of microplastics inside the fjords. The highest concentration of subsurface microplastics was found in the central part of Isfjorden and the lowest – in river plume waters, which also indicates the removal of microplastics from the inner part of fjords during an intensive river discharge. Our results may suggest that Arctic rivers flowing through unpopulated areas bring clean water and thereby reduce level of microplastic pollution in the coastal waters. In contrast to the rest of the world’s ocean, rivers are not the main source of microplastic pollution in the Arctic Ocean.

Published

2024

39. Vulnerability of Arctic-Boreal methane emissions to climate change

Author

Frans-Jan W. Parmentier, Brett F. Thornton, Anna Silyakova, and Torben R. Christensen

Subjects

methane, permafrost, wetlands, lakes, gas hydrates, arctic ocean, Environmental sciences, GE1-350

Abstract

The rapid warming of the Arctic-Boreal region has led to the concern that large amounts of methane may be released to the atmosphere from its carbon-rich soils, as well as subsea permafrost, amplifying climate change. In this review, we assess the various sources and sinks of methane from northern high latitudes, in particular those that may be enhanced by permafrost thaw. The largest terrestrial sources of the Arctic-Boreal region are its numerous wetlands, lakes, rivers and streams. However, fires, geological seeps and glacial margins can be locally strong emitters. In addition, dry upland soils are an important sink of atmospheric methane. We estimate that the net emission of all these landforms and point sources may be as much as 48.7 [13.3–86.9] Tg CH4 yr−1. The Arctic Ocean is also a net source of methane to the atmosphere, in particular its shallow shelves, but we assess that the marine environment emits a fraction of what is released from the terrestrial domain: 4.9 [0.4–19.4] Tg CH4 yr−1. While it appears unlikely that emissions from the ocean surface to the atmosphere are increasing, now or in the foreseeable future, evidence points towards a modest increase from terrestrial sources over the past decades, in particular wetlands and possibly lakes. The influence of permafrost thaw on future methane emissions may be strongest through associated changes in the hydrology of the landscape rather than the availability of previously frozen carbon. Although high latitude methane sources are not yet acting as a strong climate feedback, they might play an increasingly important role in the net greenhouse gas balance of the Arctic-Boreal region with continued climate change.

Published

2024

40. The Ocean Senses Activity Book: Enriching Ocean Literacy Through a Multisensory Approach

Author

Panieri, Giuliana, Sancak Sert, Zeynep, Maric, Filip, Poto, Margherita Paola, Murray, Emily Margaret, Panieri, Giuliana, editor, Poto, Margherita Paola, editor, and Murray, Emily Margaret, editor

Published

2024

41. Melt rates in the kilometer-size grounding zone of Petermann Glacier, Greenland, before and during a retreat

Author

Ciracì, Enrico, Rignot, Eric, Scheuchl, Bernd, Tolpekin, Valentyn, Wollersheim, Michael, An, Lu, Milillo, Pietro, Bueso-Bello, Jose-Luis, Rizzoli, Paola, and Dini, Luigi

Subjects

Climate Action, Life Below Water, Arctic Ocean, Greenland, glaciology, remote sensing, sea level

Abstract

Warming of the ocean waters surrounding Greenland plays a major role in driving glacier retreat and the contribution of glaciers to sea level rise. The melt rate at the junction of the ocean with grounded ice-or grounding line-is, however, not well known. Here, we employ a time series of satellite radar interferometry data from the German TanDEM-X mission, the Italian COSMO-SkyMed constellation, and the Finnish ICEYE constellation to document the grounding line migration and basal melt rates of Petermann Glacier, a major marine-based glacier of Northwest Greenland. We find that the grounding line migrates at tidal frequencies over a kilometer-wide (2 to 6 km) grounding zone, which is one order of magnitude larger than expected for grounding lines on a rigid bed. The highest ice shelf melt rates are recorded within the grounding zone with values from 60 ± 13 to 80 ± 15 m/y along laterally confined channels. As the grounding line retreated by 3.8 km in 2016 to 2022, it carved a cavity about 204 m in height where melt rates increased from 40 ± 11 m/y in 2016 to 2019 to 60 ± 15 m/y in 2020 to 2021. In 2022, the cavity remained open during the entire tidal cycle. Such high melt rates concentrated in kilometer-wide grounding zones contrast with the traditional plume model of grounding line melt which predicts zero melt. High rates of simulated basal melting in grounded glacier ice in numerical models will increase the glacier sensitivity to ocean warming and potentially double projections of sea level rise.

Published

2023

42. In-situ observations of gelatinous zooplankton aggregations in inshore and offshore Arctic waters

Author

Pantiukhin, Dmitrii, Soto-Angel, Joan J., Hosia, Aino, Hoving, Henk-Jan, and Havermans, Charlotte

Published

2024

43. Nutrient cycling in the Arctic and Subarctic oceans : a stable isotope study

Author

Debyser, Margot, Ganeshram, Raja, Pichevin, Laetitia, and Tuerena, Robyn

Subjects

nutrient, isotope, biogeochemistry, Arctic Ocean, polar

Abstract

Anthropogenic global warming is actively changing nutrient supply and the food web of the Arctic Ocean and the subpolar regions. This study uses the stable isotopes of dissolved silicon and nitrate, two vital nutrients for marine life, to investigate the marine biogeochemical cycling of nutrients in these regions. This work analyses datasets acquired from 7 oceanographic expeditions in three key regions: the Laptev Sea shelf, polar outflow waters of the Fram Strait (79˚N) and a full transect across the subpolar North Atlantic (50-60˚N). Hydrographic data, alongside concentrations of nitrate (NO3), dissolved silicon (DSi) and their isotopic composition (d15N-NO3, d18O-NO3, d30Si(OH)4) is presented to provide spatially and temporally integrated information on biogeochemical cycling in these regions. The overall objective of this work is to determine the processes which control nutrient budgets and cycling in the Arctic Ocean, export to the subpolar regions and the sensitivity of these processes to ongoing climate change. On the shallow Eurasian shelves of the Arctic Ocean, nitrogen is strongly depleted. This results from intense biological utilisation and significant benthic denitrification in the coastal regions, coupled with nitrogen-poor freshwater sources. Primary production in these regions is limited by N availability as a result of this. This puts a biological control on the extent of DSi utilisation in surface waters and modulates its export to the central Arctic Ocean. Over 40% of riverine DSi supplied by the Lena river is consumed and buried into the sediments of the Laptev shelf, enabled by vigorous recycling of nitrogen. Extrapolating these burial rates to the Eurasian shelf leads to an excess riverine DSi export of 3.10 ± 0.71 kmol/s through the Transpolar Drift to the central Arctic Ocean and outflowing currents. Consequently, Eurasian rivers significantly contribute to the DSi inventory of outflow polar surface waters, providing 40 ± 4% of the total DSi. By contrast, Pacific sources, which were previously estimated to be an important source of export of DSi, only contribute to 8 ± 1% of the total inventory. Glacial DSi influence from melting of the Greenland Ice sheet was found to be negligible. The Si budget is thus primarily controlled by biological processes on Arctic shelves, which currently act to enrich the d30Si(OH)4 outflowing water masses by 0.1‰ compared to Atlantic inflow (1.7‰). Climate change is increasing riverine inputs of DSi faster than N. As the export of DSi from the Arctic Ocean is dependent on N-availability, outflow waters could transport a larger flux of DSi in the future, with lowered isotopic signature. In the subpolar North Atlantic, nutrient properties of surface waters are integrated into the deep through convective water mass formation. Thus, biological assimilation and regeneration of nutrient stocks at high and low latitudes impact the nutrient inventory of North Atlantic deep waters. Surface waters of the North Atlantic have lighter d30Si(OH)4 (1.7‰) than predicted considering its nutrient deplete nature. Important processes at low latitudes act to dilute DSi concentrations of Atlantic surface waters and dampen their isotopic signature. This signal is integrated with the one of heavily utilised surface waters from the subpolar regions and the Nordic Seas into the deep North Atlantic. In recent years, deviation of the Labrador Current to the subpolar North Atlantic has reduced N assimilation. The freshwater content of the subpolar regions is predicted to increase from increased glacial melt and freshwater supply. This can act to increase stratification and decrease primary production of the region in the future. Due to the interconnectivity of the subpolar regions on the global scale, this can be reflected into the deep convective waters of the Atlantic and affect nutrient availability in the Eurasian Arctic.

Published

2023

44. Methylmercury dietary pathways and bioaccumulation in Arctic benthic invertebrates of the Beaufort Sea

Author

Christine McClelland, John Chételat, Kathleen Conlan, Alec Aitken, Mark R. Forbes, and Andrew Majewski

Subjects

Arctic Ocean, Beaufort Sea, benthic invertebrate, mercury, stable isotope, fatty acid, Environmental sciences, GE1-350, Environmental engineering, TA170-171

Abstract

This study investigated methylmercury (MeHg) concentrations in Arctic benthic invertebrates from two shelf sites in the Canadian Beaufort Sea. Carbon, nitrogen, and sulfur stable isotopes and fatty acids were measured to examine diet influences on MeHg concentrations in 476 individuals from 53 taxa of benthic invertebrates representing three different feeding guilds. Taxonomic identifications were based on DNA-barcoding and traditional taxonomy. MeHg concentrations ranged from 3 to 421 ng/g dry weight and increased over three trophic levels (δ15N range = 4.4–14.2‰). Organic matter sources had small but significant influences on MeHg bioaccumulation in the benthic food web. Carbon stable isotope ratios (δ13C, range = −25.5 to −19.8‰) were positively correlated with MeHg concentrations, suggesting greater reliance on benthic carbon contributed to higher concentrations. Sulfur stable isotopes were unrelated to MeHg concentrations. Fatty acids suggested feeding on diatoms versus dinoflagellates, and reliance on benthic resources influenced MeHg concentrations. Higher MeHg concentrations were observed at the site closer to the Mackenzie River mouth than the Cape Bathurst site. This study generated the most taxonomically rich dataset of MeHg concentrations in invertebrates from the Arctic marine benthos to date and provides a basis for future research on food web MeHg dynamics in the Canadian Beaufort Sea.

Published

2024

45. COLD CALL

Subjects

Telemarketing, Air pollution, Mounds

Abstract

IN THIS ISSUE / PINGOS COLD CALL In the remote Arctic, mysterious pingos give clues about Earth’s changing climate [I.By] DAVID PIDGEON [I.Illustration by] CLAIRE HARRUP ASK AROUND AND YOU’LL [...]

Published

2024

46. Changes in the Arctic: Background and Issues for Congress.

Author

O'Rourke, Ronald, Marshak, Anthony R., Comay, Laura B., Ramseur, Jonathan L., Frittelli, John, Ryan, Lexie, Kaboli, Emma, Sheikh, Pervaze A., and Keating-Bitonti, Caitlin

Subjects

SEA ice, CLIMATE change, GREENHOUSE gases, FISH stocking

Abstract

The diminishment of Arctic sea ice has led to increased human activities in the Arctic, and has heightened interest in, and concerns about, the region’s future. The United States, by virtue of Alaska, is an Arctic country and has substantial interests in the region. The seven other Arctic states are Russia, Canada, Iceland, Denmark (by virtue of Greenland), Norway, Sweden, and Finland. The Arctic Research and Policy Act (ARPA) of 1984 (Title I of P.L. 98-373 of July 31, 1984) “provide[s] for a comprehensive national policy dealing with national research needs and objectives in the Arctic.” The National Science Foundation (NSF) is the lead federal agency for implementing Arctic research policy. The Arctic Council, created in 1996, is the leading international forum for addressing issues relating to the Arctic. The United Nations Convention on the Law of the Sea (UNCLOS) sets forth a comprehensive regime of law and order in the world’s oceans, including the Arctic Ocean. The United States is not a party to UNCLOS. An array of climate changes in the Arctic is now documented by observing systems, with more expected with future greenhouse gas-driven climate change. Observed physical changes in the Arctic include warming ocean, soil, and air temperatures; melting permafrost; shifting vegetation and animal abundances; and altered characteristics of Arctic cyclones. A monitoring report of the Arctic Council concluded in 2019 that “the Arctic biophysical system is now clearly trending away from its previous state [in the 20th century] and into a period of unprecedented change, with implications not only within but also beyond the Arctic.” Following the end of the Cold War, the Arctic states sought to maintain the Arctic as a region of cooperation, low tension, peaceful resolution of disputes, and respect for international law. Over the past 10 to 15 years, the emergence of great power competition between the United States, Russia, and China has introduced elements of competition and tension into the Arctic’s geopolitical environment. Russia’s war in Ukraine beginning on February 24, 2022, has further affected the region’s geopolitical environment by prompting the seven Arctic states other than Russia to suspend most forms of Arctic cooperation with Russia, by prompting Finland and Sweden to apply for NATO membership (they are now NATO members), and in other ways. The Department of Defense (DOD) and the Coast Guard are devoting increased attention to the Arctic in their planning, budgeting, and operations. Whether DOD and the Coast Guard are taking sufficient actions for defending U.S. interests in the region is a topic of congressional oversight. The Coast Guard has two operational polar icebreakers and through FY2023 has received funding for procuring the first two of four or five planned new heavy polar icebreakers. The diminishment of Arctic ice could lead in coming years to increased commercial shipping on two trans-Arctic sea routes—the Northern Sea Route close to Russia, and the Northwest Passage close to Alaska and through the Canadian archipelago—though the rate of increase in the use of these routes might not be as great as sometimes anticipated in press accounts. International guidelines for ships operating in Arctic waters have been updated. Changes to the Arctic brought about by warming temperatures will likely allow more onshore and offshore exploration for oil, gas, and minerals. Warming that causes permafrost to melt could pose challenges to onshore exploration activities. Increased vessel traffic (e.g., oil and gas exploration, cruise ships, expanded fishing activities) in the Arctic increase the risk of pollution in Arctic waters. Cleaning up oil spills in ice-covered waters will be more difficult than in other areas, primarily because effective strategies for cleaning up oil spills in ice-covered waters have yet to be developed. Changes in the Arctic could result in migration of fish stocks to new waters, and could affect protected species. The United States is working with other countries regarding the management of Arctic fish stocks. [ABSTRACT FROM AUTHOR]

Published

2024

47. Genetic and Structural Diversity of Prokaryotic Ice-Binding Proteins from the Central Arctic Ocean

Author

Winder, Johanna C, Boulton, William, Salamov, Asaf, Eggers, Sarah Lena, Metfies, Katja, Moulton, Vincent, and Mock, Thomas

Subjects

Microbiology, Biochemistry and Cell Biology, Biological Sciences, Genetics, Generic health relevance, Life Below Water, Prokaryotic Cells, Carrier Proteins, Protein Domains, Seawater, Oceans and Seas, Arctic Ocean, DUF3494, MAGs, MOSAiC expedition, domain shuffling, ice-binding proteins, metagenomics, polar genomics

Abstract

Ice-binding proteins (IBPs) are a group of ecologically and biotechnologically relevant enzymes produced by psychrophilic organisms. Although putative IBPs containing the domain of unknown function (DUF) 3494 have been identified in many taxa of polar microbes, our knowledge of their genetic and structural diversity in natural microbial communities is limited. Here, we used samples from sea ice and sea water collected in the central Arctic Ocean as part of the MOSAiC expedition for metagenome sequencing and the subsequent analyses of metagenome-assembled genomes (MAGs). By linking structurally diverse IBPs to particular environments and potential functions, we reveal that IBP sequences are enriched in interior ice, have diverse genomic contexts and cluster taxonomically. Their diverse protein structures may be a consequence of domain shuffling, leading to variable combinations of protein domains in IBPs and probably reflecting the functional versatility required to thrive in the extreme and variable environment of the central Arctic Ocean.

Published

2023

48. Bacterioplankton taxa compete for iron along the early spring–summer transition in the Arctic Ocean.

Author

Puente‐Sánchez, Fernando, Macías‐Pérez, Luis Alberto, Campbell, Karley L., Royo‐Llonch, Marta, Balagué, Vanessa, Sánchez, Pablo, Tamames, Javier, Mundy, Christopher John, and Pedrós‐Alió, Carlos

Subjects

*GAMMAPROTEOBACTERIA, *IRON, *MEMBRANE transport proteins, *ATP-binding cassette transporters, *BACTERIOPLANKTON, *SEA ice

Abstract

Microbial assemblages under the sea ice of the Dease Strait, Canadian Arctic, were sequenced for metagenomes of a small size fraction (0.2–3 μm). The community from early March was typical for this season, with Alpha‐ and Gammaproteobacteria as the dominant taxa, followed by Thaumarchaeota and Bacteroidetes. Toward summer, Bacteroidetes, and particularly the genus Polaribacter, became increasingly dominant, followed by the Gammaproteobacteria. Analysis of genes responsible for microbial acquisition of iron showed an abundance of ABC transporters for divalent cations and ferrous iron. The most abundant transporters, however, were the outer membrane TonB‐dependent transporters of iron‐siderophore complexes. The abundance of iron acquisition genes suggested this element was essential for the microbial assemblage. Interestingly, Gammaproteobacteria were responsible for most of the siderophore synthesis genes. On the contrary, Bacteroidetes did not synthesize siderophores but accounted for most of the transporters, suggesting a role as cheaters in the competition for siderophores as public goods. This cheating ability of the Bacteroidetes may have contributed to their dominance in the summer. [ABSTRACT FROM AUTHOR]

Published

2024

49. Arctic Oceanic Carbon Cycle: A Comprehensive Review of Mechanisms, Regulations, and Models.

Author

Ye, Xudong, Zhang, Baiyu, Dawson, Justin, Amon, Christabel D., Ezechukwu, Chisom, Igwegbe, Ezinne, Kang, Qiao, Song, Xing, and Chen, Bing

Subjects

CARBON cycle, MARITIME shipping, EVIDENCE gaps, ARCTIC climate, SEA ice, MARINE west coast climate

Abstract

Understanding the oceanic carbon cycle, particularly in the Arctic regions, is crucial for addressing climate change. However, significant research gaps persist, especially regarding climate effects on the oceanic carbon cycle in these regions. This review systematically explores Arctic-related research, focusing on mechanisms, regulatory frameworks, and modelling approaches in the oceanic carbon cycle, carbon sink, climate change impact, and maritime shipping. The findings highlight the Arctic's limited observer presence and high operational costs, hindering the data availability and studies on carbon-cycle changes. This underscores the need to integrate real-time Arctic Ocean monitoring data. Carbon sink research urgently requires direct methods to measure anthropogenic carbon uptake and address uncertainties in air–ocean carbon fluxes due to sea ice melting. Unlike terrestrial carbon cycling research, carbon-cycle studies in the oceans, which are essential for absorbing anthropogenic emissions, receive insufficient attention, especially in the Arctic regions. Numerous policies often fall short in achieving effective mitigation, frequently depending on voluntary or market-based approaches. Analyzing carbon-cycle and sink models has uncovered limitations, primarily due to their global perspective, hampering in-depth assessments of climate change effects on the Arctic regions. To pave the way for future research, enhancing Arctic Ocean climate data availability is recommended, as well as fostering international cooperation in carbon-cycle research, enforcing carbon policies, and improving regional modelling in the Arctic Ocean. [ABSTRACT FROM AUTHOR]

Published

2024

50. Decline in Ice Coverage and Ice-Free Period Extension in the Kara and Laptev Seas during 1979–2022.

Author

Shabanov, Pavel, Osadchiev, Alexander, Shabanova, Natalya, and Ogorodov, Stanislav

Subjects

*SEA ice, *MICROWAVE remote sensing, *SEAWATER

Abstract

The duration of ice-free periods in different parts of the Arctic Ocean plays a great role in processes in the climate system and defines the most comfortable sea ice conditions for economic activity. Based on satellite-derived sea ice concentration data acquired by passive microwave instruments, we identified the spatial distribution of the dates of sea ice retreat (DOR), dates of sea ice advance (DOA), and the resulting ice-free period duration (IFP) between these days for the Kara and Laptev seas during 1979–2022. The monthly decline in sea ice extent was detected from June to October in both seas, i.e., during the whole ice-free period. The annual mean sea ice extent during 2011–2021 decreased by 19.0% and 12.8% relative to the long-term average during 1981–2010 in the Kara and Laptev seas, respectively. The statistically significant (95% confidence level) positive IFP trends were detected for the majority of areas of the Kara and Laptev seas. Averaged IFP trends were estimated equal to +20.2 day/decade and +16.2 day/decade, respectively. The observed DOR tendency to earlier sea ice melting plays a greater role in the total IFP extension, as compared to later sea ice formation related to the DOA tendency. We reveal that regions of inflow of warm Atlantic waters to the Kara Sea demonstrate the largest long-term trends in DOA, DOR, and IFP associated with the decrease in ice coverage, that highlights the process of atlantification. Also, the Great Siberian Polynya in the Laptev Sea is the area of the largest long-term decreasing trend in DOR. [ABSTRACT FROM AUTHOR]

Published

2024