Arctic warming interrupts the Transpolar Drift and affects long-range transport of sea ice and ice-rafted matter

Krumpen, Thomas; Belter, Hans Jakob; Boetius, Antje; Damm, Ellen; Haas, Christian; Hendricks, Stefan; Nicolaus, Marcel; Nöthig, Eva‐Maria; Paul, Stephan; Peeken, Ilka; Ricker, Robert; Stein, Rüdiger

doi:10.1038/s41598-019-41456-y

Cited by 121 publications

(158 citation statements)

References 55 publications

(50 reference statements)

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“…A follow‐up data set that extends this record using AMSR2 data is currently under development. As could be shown in this study, previously observed positive trends in IP (Preußer et al, ) on the Siberian shelf seas are also found in the 16‐year data set, which underlines an apparent change in polynya dynamics in the Eastern Arctic and, connected to that, changing Transpolar Drift characteristics (Krumpen et al, ).…”

Section: Discussionsupporting

confidence: 87%

Retrieval of Wintertime Sea Ice Production in Arctic Polynyas Using Thermal Infrared and Passive Microwave Remote Sensing Data

et al. 2019

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Precise knowledge of wintertime sea ice production in Arctic polynyas is not only required to enhance our understanding of atmosphere‐sea ice‐ocean interactions but also to verify frequently utilized climate and ocean models. Here, a high‐resolution (2‐km) Moderate Resolution Imaging Spectroradiometer (MODIS) thermal infrared satellite data set featuring spatial and temporal characteristics of 17 Arctic polynya regions for the winter seasons 2002/2003 to 2017/2018 is directly compared to an akin low‐resolution Advanced Microwave Scanning Radiometer‐EOS (AMSR‐E) passive microwave data set for 2002/2003 to 2010/2011. The MODIS data set is purely based on a 1‐D energy‐balance model, where thin‐ice thicknesses (≤ 20 cm) are directly derived from ice‐surface temperature swath data and European Centre for Medium‐Range Weather Forecasts Re‐Analysis‐Interim atmospheric reanalysis data on a quasi‐daily basis. Thin‐ice thicknesses in the AMSR‐E data set are derived empirically. Important polynya properties such as areal extent and potential thermodynamic ice production can be estimated from both pan‐Arctic data sets. Although independently derived, our results show that both data sets feature quite similar spatial and temporal variations of polynya area (POLA) and ice production (IP), which suggests a high reliability. The average POLA (average accumulated IP) for all Arctic polynyas combined derived from both MODIS and AMSR‐E are 1.99×105 km2 (1.34×103 km3) and 2.29×105 km2 (1.31×103 km3), respectively. Narrow polynyas in areas such as the Canadian Arctic Archipelago are notably better resolved by MODIS. Analysis of 16 winter seasons provides an evaluation of long‐term trends in POLA and IP, revealing the significant increase of ice formation in polynyas along the Siberian coast.

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Section: Discussionsupporting

confidence: 87%

Retrieval of Wintertime Sea Ice Production in Arctic Polynyas Using Thermal Infrared and Passive Microwave Remote Sensing Data

et al. 2019

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“…Ice transport along long‐distance pathways are predicted to diminish in favor of ice exchange between neighboring EEZs by the end of the 21st century under the high emissions scenario, specifically shifting to the EEZs downstream of each EEZ of formation. This is the result of a projected lengthening of the melt season, which decreases average transit times to less than 1 yr for the CESM‐LE, continuing the trend recently reported by Krumpen et al () and Newton et al (). In fact, the CESM‐LE shows a decrease in the fraction of transnational ice exchange between the periods of 2031–2050 and 2081–2100, whereas the CESM‐LW continues to see an increase.…”

Section: Discussionsupporting

confidence: 84%

Increased Transnational Sea Ice Transport Between Neighboring Arctic States in the 21^st Century

et al. 2020

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The Arctic is undergoing a rapid transition toward a seasonal ice regime, with widespread implications for the polar ecosystem, human activities, as well as the global climate. Here we focus on how the changing ice cover impacts transborder exchange of sea ice between the exclusive economic zones of the Arctic states. We use the Sea Ice Tracking Utility, which follows ice floes from formation to melt, in conjunction with output diagnostics from two ensembles of the Community Earth System Model that follow different future emissions scenarios. The Community Earth System Model projects that by midcentury, transnational ice exchange will more than triple, with the largest increase in the amount of transnational ice originating from Russia and the Central Arctic. However, long‐distance ice transport pathways are predicted to diminish in favor of ice exchanged between neighboring countries. By the end of the 21st century, we see a large difference between the two future emissions scenarios considered: Consistent nearly ice‐free summers under the high emissions scenario act to reduce the total fraction of transnational ice exchange compared to midcentury, whereas the low emissions scenario continues to see an increase in the proportion of transnational ice. Under both scenarios, transit times are predicted to decrease to less than 2 yr by 2100, compared to a maximum of 6 yr under present‐day conditions and 2.5 yr by midcentury. These significant changes in ice exchange and transit time raise important concerns regarding risks associated with ice‐rafted contaminants.

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“…Mobile sea ice floes in the Arctic Ocean are capable of entrapping contaminants along their drift pathways and playing a role in the redistribution of contaminants due to their eventual release upon melting of the ice 2,16,19 . Estimating backward sea ice trajectories is an important tool that facilitates an examination of sea ice sources, drift pathways, thickness changes and atmospheric processes acting on the ice cover 2,[28][29][30] . When utilized in microplastic studies, backward sea ice trajectory data (i.e.…”

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confidence: 99%

Microplastics in sea ice and seawater beneath ice floes from the Arctic Ocean

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Gårdfeldt

Krumpen

et al. 2020

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Within the past decade, an alarm was raised about microplastics in the remote and seemingly pristine Arctic Ocean. To gain further insight about the issue, microplastic abundance, distribution and composition in sea ice cores (n = 25) and waters underlying ice floes (n = 22) were assessed in the Arctic Central Basin (ACB). Potential microplastics were visually isolated and subsequently analysed using Fourier Transform Infrared (FT-IR) Spectroscopy. Microplastic abundance in surface waters underlying ice floes (0-18 particles m −3) were orders of magnitude lower than microplastic concentrations in sea ice cores (2-17 particles L −1). No consistent pattern was apparent in the vertical distribution of microplastics within sea ice cores. Backward drift trajectories estimated that cores possibly originated from the Siberian shelves, western Arctic and central Arctic. Knowledge about microplastics in environmental compartments of the Arctic Ocean is important in assessing the potential threats posed by microplastics to polar organisms. Within the past decade, microplastic pollution emerged as an issue of concern in the Arctic Ocean due to the discovery of these contaminants in its sea ice 1,2 , surface and sub-surface waters 3-8 , deep sea sediments 9-11 , biota 4,6,12,13 and mostly recently its snow 14. Of the environmental compartments in this remote oceanic basin, it was shown that sea ice can function as a temporal sink, a secondary source and a transport medium for microplastics 1,2. Historically, however, observational records of 'dirty ice' , examination of Arctic ice cores, laboratory-based experiments and modelling studies were the first to highlight the potential for sea ice in the Arctic Ocean to trap, transport and redistribute sediments and various contaminants (i.e. metals, organochlorines, organophosphates, polycyclic aromatic hydrocarbons) 15-27. Microplastics (plastic particles <5 mm in diameter) were first discovered in subsections of 4 ice cores retrieved from various locations in the Arctic Ocean 1. In this initial study, a total of 6 types of synthetic polymers were reported in the ice cores and microplastic concentrations in Arctic sea ice were estimated (based on extrapolations) to be between (1.3-9.6) × 10 4 particles m −3. A second study 2 , subsequently examined 5 sea ice cores from the Arctic Ocean, reported on the presence of smaller (<100 µm in diameter), more diverse types of synthetic polymers (n = 17) and estimated (based on extrapolations) microplastic concentrations in Arctic sea ice to range between (1.1 × 10 6)-(1.2 × 10 7) particles m −3. Both studies 1,2 , while limited in scale and extent, collectively suggested that sea ice can function as a sink, source and transport medium for microplastics in the Arctic Ocean. Within this remote oceanic basin, microplastic entrapment within sea ice potentially occurs during sea ice formation and drift while microplastic release occurs upon the melting of sea ice 1,2,14. In the Arctic Ocean, while sea ice formation occurs over the central Arcti...

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Arctic warming interrupts the Transpolar Drift and affects long-range transport of sea ice and ice-rafted matter

Cited by 121 publications

References 55 publications

Retrieval of Wintertime Sea Ice Production in Arctic Polynyas Using Thermal Infrared and Passive Microwave Remote Sensing Data

Retrieval of Wintertime Sea Ice Production in Arctic Polynyas Using Thermal Infrared and Passive Microwave Remote Sensing Data

Increased Transnational Sea Ice Transport Between Neighboring Arctic States in the 21^st Century

Microplastics in sea ice and seawater beneath ice floes from the Arctic Ocean

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Arctic warming interrupts the Transpolar Drift and affects long-range transport of sea ice and ice-rafted matter

Cited by 121 publications

References 55 publications

Retrieval of Wintertime Sea Ice Production in Arctic Polynyas Using Thermal Infrared and Passive Microwave Remote Sensing Data

Retrieval of Wintertime Sea Ice Production in Arctic Polynyas Using Thermal Infrared and Passive Microwave Remote Sensing Data

Increased Transnational Sea Ice Transport Between Neighboring Arctic States in the 21st Century

Microplastics in sea ice and seawater beneath ice floes from the Arctic Ocean

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Increased Transnational Sea Ice Transport Between Neighboring Arctic States in the 21^st Century