Your search keyword '"Krumpen, Thomas"' showing total 5 results

1. Export of Algal Biomass from the Melting Arctic Sea Ice

Author

Boetius, Antje, Albrecht, Sebastian, Bakker, Karel, Bienhold, Christina, Felden, Janine, Fernández-Méndez, Mar, Hendricks, Stefan, Katlein, Christian, Lalande, Catherine, Krumpen, Thomas, Nicolaus, Marcel, Peeken, Ilka, Rabe, Benjamin, Rogacheva, Antonina, Rybakova, Elena, Somavilla, Raquel, and Wenzhöfer, Frank

Published

2013

2. Recent observations of superimposed ice and snow ice on sea ice in the northwestern Weddell Sea.

Author

Arndt, Stefanie, Haas, Christian, Meyer, Hanno, Peeken, Ilka, and Krumpen, Thomas

Subjects

SEA ice, ICE, SNOW accumulation, ICE cores, OXYGEN isotopes, SURFACE energy, ISOTOPIC analysis, SEASONS

Abstract

Recent low summer sea ice extent in the Weddell Sea raises questions about the contributions of dynamic and thermodynamic atmospheric and oceanic energy fluxes. The roles of snow, superimposed ice, and snow ice are particularly intriguing, as they are sensitive indicators of changes in atmospheric forcing and as they could trigger snow–albedo feedbacks that could accelerate ice melt. Here we present snow depth data and ice core observations of superimposed ice and snow ice collected in the northwestern Weddell Sea in late austral summer 2019, supplemented by airborne ice thickness measurements. Texture, salinity, and oxygen isotope analyses showed mean thicknesses of superimposed and snow ice of 0.11±0.11 and 0.22±0.22 m, respectively, or 3 % to 54 % of total ice thickness. Mean snow depths ranged between 0.46±0.29 m in the south to 0.05±0.06 m in the north, with mean and modal total ice thicknesses of 4.12±1.87 to 1.62±1.05 m and 3.9 to 0.9 m, respectively. These snow and ice properties are similar to results from previous studies, suggesting that the ice's summer surface energy balance and related seasonal transition of snow properties have changed little in past decades. This is supported by our additional analyses of the summer energy balance using atmospheric reanalysis data and by melt onset observations from satellite scatterometry showing few recent changes. [ABSTRACT FROM AUTHOR]

Published

2021

3. MOSAiC drift expedition from October 2019 to July 2020: sea ice conditions from space and comparison with previous years.

Author

Krumpen, Thomas, von Albedyll, Luisa, Goessling, Helge F., Hendricks, Stefan, Juhls, Bennet, Spreen, Gunnar, Willmes, Sascha, Belter, H. Jakob, Dethloff, Klaus, Haas, Christian, Kaleschke, Lars, Katlein, Christian, Tian-Kunze, Xiangshan, Ricker, Robert, Rostosky, Philip, Rückert, Janna, Singha, Suman, and Sokolova, Julia

Subjects

*ARCTIC climate, *SEA ice, *GLACIAL drift, *ICE

Abstract

We combine satellite data products to provide a first and general overview of the physical sea ice conditions along the drift of the international Multidisciplinary drifting Observatory for the Study of Arctic Climate (MOSAiC) expedition and a comparison with previous years (2005–2006 to 2018–2019). We find that the MOSAiC drift was around 20 % faster than the climatological mean drift, as a consequence of large-scale low-pressure anomalies prevailing around the Barents–Kara–Laptev sea region between January and March. In winter (October–April), satellite observations show that the sea ice in the vicinity of the Central Observatory (CO; 50 km radius) was rather thin compared to the previous years along the same trajectory. Unlike ice thickness, satellite-derived sea ice concentration, lead frequency and snow thickness during winter months were close to the long-term mean with little variability. With the onset of spring and decreasing distance to the Fram Strait, variability in ice concentration and lead activity increased. In addition, the frequency and strength of deformation events (divergence, convergence and shear) were higher during summer than during winter. Overall, we find that sea ice conditions observed within 5 km distance of the CO are representative for the wider (50 and 100 km) surroundings. An exception is the ice thickness; here we find that sea ice within 50 km radius of the CO was thinner than sea ice within a 100 km radius by a small but consistent factor (4 %) for successive monthly averages. Moreover, satellite acquisitions indicate that the formation of large melt ponds began earlier on the MOSAiC floe than on neighbouring floes. [ABSTRACT FROM AUTHOR]

Published

2021

4. The MOSAiC ice floe: sediment-laden survivor from the Siberian shelf.

Author

Krumpen, Thomas, Birrien, Florent, Kauker, Frank, Rackow, Thomas, von Albedyll, Luisa, Angelopoulos, Michael, Belter, H. Jakob, Bessonov, Vladimir, Damm, Ellen, Dethloff, Klaus, Haapala, Jari, Haas, Christian, Harris, Carolynn, Hendricks, Stefan, Hoelemann, Jens, Hoppmann, Mario, Kaleschke, Lars, Karcher, Michael, Kolabutin, Nikolai, and Lei, Ruibo

Subjects

*SEA ice, *ICE, *ARCTIC climate, *METEOROLOGICAL stations, *ICE cores, ARCTIC exploration

Abstract

In September 2019, the research icebreaker Polarstern started the largest multidisciplinary Arctic expedition to date, the MOSAiC (Multidisciplinary drifting Observatory for the Study of Arctic Climate) drift experiment. Being moored to an ice floe for a whole year, thus including the winter season, the declared goal of the expedition is to better understand and quantify relevant processes within the atmosphere–ice–ocean system that impact the sea ice mass and energy budget, ultimately leading to much improved climate models. Satellite observations, atmospheric reanalysis data, and readings from a nearby meteorological station indicate that the interplay of high ice export in late winter and exceptionally high air temperatures resulted in the longest ice-free summer period since reliable instrumental records began. We show, using a Lagrangian tracking tool and a thermodynamic sea ice model, that the MOSAiC floe carrying the Central Observatory (CO) formed in a polynya event north of the New Siberian Islands at the beginning of December 2018. The results further indicate that sea ice in the vicinity of the CO (<40 km distance) was younger and 36 % thinner than the surrounding ice with potential consequences for ice dynamics and momentum and heat transfer between ocean and atmosphere. Sea ice surveys carried out on various reference floes in autumn 2019 verify this gradient in ice thickness, and sediments discovered in ice cores (so-called dirty sea ice) around the CO confirm contact with shallow waters in an early phase of growth, consistent with the tracking analysis. Since less and less ice from the Siberian shelves survives its first summer (Krumpen et al., 2019), the MOSAiC experiment provides the unique opportunity to study the role of sea ice as a transport medium for gases, macronutrients, iron, organic matter, sediments and pollutants from shelf areas to the central Arctic Ocean and beyond. Compared to data for the past 26 years, the sea ice encountered at the end of September 2019 can already be classified as exceptionally thin, and further predicted changes towards a seasonally ice-free ocean will likely cut off the long-range transport of ice-rafted materials by the Transpolar Drift in the future. A reduced long-range transport of sea ice would have strong implications for the redistribution of biogeochemical matter in the central Arctic Ocean, with consequences for the balance of climate-relevant trace gases, primary production and biodiversity in the Arctic Ocean. [ABSTRACT FROM AUTHOR]

Published

2020

5. Large-scale ice thickness distribution of first-year sea ice in spring and summer north of Svalbard.

Author

RENNER, Angelika H. H., HENDRICKS, Stefan, GERLAND, Sebastian, BECKERS, Justin, HAAS, Christian, and KRUMPEN, Thomas

Subjects

SEA ice, THICKNESS measurement, ELECTROMAGNETIC induction, SEASONS, ICE, EQUIPMENT & supplies

Abstract

The large-scale thickness distribution of sea ice was measured during several campaigns in the European Arctic north of Svalbard from 2007 using an airborne electromagnetic induction device. In August 2010 and April-May 2011, this was complemented by extensive on-ice work including measurements of snow thickness and freeboard. Ice thicknesses show a clear difference between the seasons, with thicker ice during spring than in summer. In spring 2011, negative freeboard and flooding were observed as a result of the extensive snow cover. We find that the characteristics of the first-year sea ice allow combining observations from different years. The ice thickness in the marginal ice zone increases with increasing latitude and increasing distance to the ice edge; however, in the inner ice pack from ~100 km from the ice edge the thickness remains almost constant. Modal ice thickness in spring reaches 2.4m whereas in summer it is 1.0-1.4m. Our study provides new insight into ice thickness distributions of a typical ice cover consisting of mainly first- and second-year ice, which may become the dominant ice type in the Arctic in the future. [ABSTRACT FROM AUTHOR]

Published

2013