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2. Heavy and Light Mineral Association of Late Quaternary Permafrost Deposits in Northeastern Siberia

Author

Schirrmeister, Lutz, Schwamborn, Georg, Matthes, Heidrun, Grosse, Guido, Klimova, Irina, Kunitsky, Viktor V., Siegert, Christine, and Wetterich, Sebastian

Subjects
General Earth and Planetary Sciences
Abstract

We studied heavy and light mineral associations from two grain-size fractions (63–125 μm, 125–250 µm) from 18 permafrost sites in the northern Siberian Arctic in order to differentiate local versus regional source areas of permafrost aggradation on the late Quaternary time scale. The stratigraphic context of the studied profiles spans about 200 ka covering the Marine Isotope Stage (MIS) 7 to MIS 1. Heavy and light mineral grains are mostly angular, subangular or slightly rounded in the studied permafrost sediments. Only grains from sediments with significantly longer transport distances show higher degrees of rounding. Differences in the varying heavy and light mineral associations represent varying sediment sources, frost weathering processes, transport mechanisms, and post-sedimentary soil formation processes of the deposits of distinct cryostratigraphic units. We summarized the results of 1141 microscopic mineral analyses of 486 samples in mean values for the respective cryostratigraphic units. We compared the mineral associations of all 18 sites along the Laptev Sea coast, in the Lena Delta, and on the New Siberian Archipelago to each other and used analysis of variance and cluster analysis to characterize the differences and similarities among mineral associations. The mineral associations of distinct cryostratigraphic units within several studied profiles differ significantly, while others do not. Significant differences between sites as well as between single cryostratigraphic units at an individual site exist in mineral associations, heavy mineral contents, and mineral coefficients. Thus, each study site shows individual, location-specific mineral association. The mineral records originate from multiple locations covering a large spatial range and show that ratios of heavy and light mineral loads remained rather stable over time, including glacial and interglacial periods. This suggests mostly local sediment sources and highlights the importance of sediment reworking under periglacial regimes through time, including for example the formation of MIS 1 thermokarst and thermo-erosional deposits based on remobilized MIS 3 and 2 Yedoma Ice Complex deposits. Based on the diverse mineralogical results our study supports the viewpoint that Yedoma Ice Complex deposits are mainly results of local and polygenetic formations (including local aeolian relocation) superimposed by cryogenic weathering and varying climate conditions rather than exclusive long distance aeolian transport of loess, which would have highly homogenized the deposits across large regions.

Published
2022
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3. 25 years of joint Yedoma Ice Complex studies in Arctic Russia, especially in Sakha/Yakutia

Author

Grosse, Guido, Schirrmeister, Lutz, Wetterich, Sebastian, Strauss, Jens, Meyer, Hanno, Opel, Thomas, Siegert, Christine, Windirsch, Torben, Jongejans, Loeka L., Laboor, Sebastian, Diekmann, Bernhard, Andreev, Andrei, Hubberten, Hans-Wolfgang, Kunitsky, Viktor V., Fedorov, Alexander N., Grigoriev, Mikhail N., Derevyagin, Alexander Yu, Tumskoy, Vladimir, Kuznetsova, Tatyana, Kienast, Frank, and Ulrich, Mathias

Abstract

Since 1994, permafrost deposits of the Siberian Yedoma region have been in the focus of the joint Russian-German scientific cooperation in terrestrial Polar research (Figure 1). These studies focused on cryostratigraphic, geochemical, geochronological, and paleontological characteristics at more than 25 individual study sites of the late Pleistocene Yedoma Ice Complex in Siberia and provided a detailed insight into the paleoenvironments and paleoclimate for the westernmost part of Beringia. The multidisciplinary investigations resulted in new ideas and discussions in the ongoing scientific debate on the origin of Yedoma Ice Complex and the main periglacial processes involved in its formation (1,2,3). The Yedoma Ice Complex is an ice-rich type of permafrost deposit widely distributed across Beringia. The Ice Complex aggradation is mainly controlled by the growth of syngenetic ice wedge polygons contributing up to 60 vol% of the entire formation. The clastic sedimentation of ice-oversaturated Yedoma deposits with considerable organic matter content is further controlled by local conditions such as source rocks and periglacial weathering processes, paleotopography, and temporary surface stabilization with autochthonous peat growth and soil formation. Key processes include alluvial, fluvial, and niveo-aeolian transport (4) as well as accumulation in ponding waters and continued in-situ frost weathering over millennial time-scales. Important post-depositional processes affecting Yedoma deposits are solifluction, cryoturbation, and pedogenesis. Major joint Russian-German field studies were conducted on Taymyr Peninsula (5,6,7,8,9,10,11), along the western and central Laptev Sea coasts (12,13,14,15,16,17,18), in the Lena Delta (19,20,21,22), on islands of the New Siberian Archipelago (23,24,25,26,27,28), and the adjacent mainland (29). Further study sites were conducted in the Kolyma Lowland (30), the Yana Highlands (31,32), in the foothills of the Verkhoyan Mountains (33,34,35,36), and in Central Yakutia (37). Comprehensive sampling and further analytical work included not only the Yedoma Ice Complex itself but also included its stratigraphic context of older underlying sequences and younger overlying deposits. The latter often are subaerial or subaquatic deposits associated with late-Glacial to Holocene thermokarst dynamics that led to Yedoma degradation during the deglacial and Holocene warming of these regions (38,39,40). Figure 1: Joint Russian-German fieldwork sites in NE Siberia labeled with the year of expedition. Besides geomorphological and cryolithological studies, extensive paleo-ecological investigations were carried out on zoological (41,42,43,44,45) and botanic fossils (46,47,48,49,50,51) to derive quantitative and qualitative reconstructions late Pleistocene Beringian environments and climate conditions. New methods in geochronology were also tested (52,53,54,55). In addition to the sedimentary components of the frozen deposits, segregated ground ice and in particular the large syngenetic ice wedges of Yedoma Ice Complex were also studied as geochemical and stable isotope archives of paleoclimate (56,57,58, 59,60,61,62). In addition, a range of remote sensing methods in combination with GIS analyses (63,64,65) and geophysical surveys (66) were used for large-scale analyses of landscape changes associated with Yedoma Ice Complex degradation (67,68,69). In the last few years, an additional important focus has been on using modern biogeochemical methods of organic matter analysis to characterize the frozen organic matter in Yedoma Ice Complex deposits and for permafrost carbon pool calculations (70, 71,72,73,74,75,76,77) as well as microbiological studies (78) and genetic studies on fossil DNA (79,80). The rich body of scientific data and literature produced in Russian-German co-authorship within the more than 25 years of joint research on Yedoma Ice Complex represents an important cornerstone for understanding the Late Quaternary evolution of Siberian Yedoma regions, its role in the Earth System, and its feedbacks with climate and ecosystems. References 1. Schirrmeister, L., Dietze, E., Matthes, H., Grosse, G., Strauss, J., Laboor, S., Ulrich, M., Kienast, F., and Wetterich, S. (2020) The genesis of Yedoma Ice Complex permafrost – grain-size endmember modeling analysis from Siberia and Alaska, E&G Quaternary Sci. J., 69, 33–53, doi: 10.5194/egqsj-69-33-2020. 2. Schirrmeister, L., Froese, D., Tumskoy, V., Grosse,G., Wetterich, S. (2013.) Yedoma: Late Pleistocene ice-rich syngenetic permafrost of Beringia. In: Elias S.A. (ed.) The Encyclopedia of Quaternary Science 2nd edition, vol. 3, pp. 542-552. Amsterdam: Elsevier. 3. Schirrmeister, L., Kunitsky, V.V., Grosse, G., Wetterich, S., Meyer, H., Schwamborn, G., Babiy, O., Derevyagin, A.Y., and Siegert, C.: Sedimentary characteristics and origin of the Late Pleistocene Ice Complex on North-East Siberian Arctic coastal lowlands and islands - a review. Quaternary International 241, 3-25, doi: 10.1016/j.quaint.2010.04.004, 2011. 4. Kunitsky, V., Schirrmeister, L., Grosse, G., Kienast, F. (2002). Snow patches in nival landscapes and their role for the Ice Complex formation in the Laptev Sea coastal lowlands, Polarforschung, 70, 53-67, doi:10.2312/polarforschung.70.53. 5. Andreev, A. , Siegert, C. , Klimanov, V. A. , Derevyagin, A. Y. , Shilova, G. N. and Melles, M. (2002) Late Pleistocene and Holocene vegetation and climate changes in the Taymyr lowland, Northern Siberia Quaternary research, 57, pp. 138-150 . 6. Andreev, A. , Tarasov, P. E. , Siegert, C. , Ebel, T. , Klimanov, V. A. , Melles, M. , Bobrov, A. A. , Derevyagin, A. Y. , Lubinski, D. J. and Hubberten, H. W. (2003) Vegetation and climate changes on the northern Taymyr, Russia during the Upper Pleistocene and Holocene reconstructed from pollen records , Boreas, 32 (3), pp. 484-505 . 7. Chizhov, A. B. , Derevyagin, A. Y. , Simonov, E. F. , Hubberten, H. W. and Siegert, C. (1997) Isotopic composition of ground ice at the Labaz Lake region (Taymyr). Kriosfera Zemlii (Earth Cryoshere), 1, No 3, pp. 79-84 . (in Russian), 8. Derevyagin, A.Yu., Chizhov, A.B., Brezgunov, V.S., Siegert, C., Hubberten, H.-W., 1999.Isotopic composition of ice wedges of Cape Sabler (Lake Taymyr). Kriosfera Zemlii (Earth Cryosphere) 3/3, 41-49 (in Russian). 9. Kienast, F., Siegert, C., Dereviagin, A., Mai, H.D. Climatic implications of Late Quaternary plant macrofossil assemblages from the Taymyr Peninsula, Siberia, Global and Planetary Change, Volume 31, Issues 1–4, 265-281, 2001, https://doi.org/10.1016/S0921-8181(01)00124-2. 10. Kienel, U. , Siegert, C. and Hahne, J. (1999) Late Quarternary paeloenvironmental reconstruction from a permafrost sequence (Northsiberian Lowland, SE Taymyr Peninsula) - a multidisciplinary case study, Boreas, 28 (1), pp. 181-193 . 11. Siegert C., Derevyagin A.Y., Shilova G.N., Hermichen WD., Hiller A. (1999) Paleoclimatic Indicators from Permafrost Sequences in the Eastern Taymyr Lowland. In: Kassens H. et al. (eds) Land-Ocean Systems in the Siberian Arctic. Springer, Berlin, Heidelberg. 12. Bobrov, A.A., Müller, S., Chizhikova, N.A., Schirrmeister, L., Andreev, A.A.(2009).Testate Amoebae in Late Quaternary Sediments of the Cape Mamontov Klyk (Yakutia), Biology Bulletin, 36(4), 363-372. 13. Schirrmeister, L., Grosse, G., Kunitsky, V., Magens, D., Meyer, H., Dereviagin, A., Kuznetsova, T., Andreev, A., Babiy, O., Kienast, F., Grigoriev, M., Overduin, P.P., and Preusser, F.: Periglacial landscape evolution and environmental changes of Arctic lowland areas for the last 60,000 years (Western Laptev Sea coast, Cape Mamontov Klyk), Polar Research, 27(2), 249-272, doi: 10.1111/j.1751-8369.2008.00067.x, 2008. 14. Winterfeld, M., Schirrmeister, L., Grigoriev, M., Kunitsky, V.V., Andreev, A., and Overduin, P.P.: Permafrost and Landscape Dynamics during the Late Pleistocene, Western Laptev Sea Shelf, Siberia, Boreas 40(4), 697–713, doi: 10.1111/j.1502-3885.2011.00203.x, 2011. 15. Siegert, C., Schirrmeister, L., and Babiy, O.: The sedimentological, mineralogical and geochemical composition of late Pleistocene deposits from the ice complex on the Bykovsky peninsula, northern Siberia, Polarforschung, 70, 2000, 3-11, doi: 10.2312/polarforschung.70.3, 2002. 16. Schirrmeister, L., Siegert, C., Kuznetsova, T., Kuzmina, S., Andreev, A.A., Kienast, F., Meyer, H., and Bobrov, A.A.: Paleoenvironmental and paleoclimatic records from permafrost deposits in the Arctic region of Northern Siberia, Quaternary International, 89, 97-118, doi: 10.1016/S1040-6182(01)00083-0, 2002. 17. Schirrmeister, L., Siegert, C., Kunitzky, V.V., Grootes, P.M., and Erlenkeuser, H.: Late Quaternary ice-rich permafrost sequences as a paleoenvironmental archive for the Laptev Sea Region in northern Siberia, International Journal of Earth Sciences, 91, 154-167, doi: 10.1007/s005310100205, 2002. 18. Schirrmeister, L., Schwamborn, G., Overduin, P.P., Strauss, J., Fuchs, M.C., Grigoriev, M., Yakshina, I., Rethemeyer, J., Dietze, E., and Wetterich, S.: Yedoma Ice Complex of the Buor Khaya Peninsula (southern Laptev Sea), Biogeosciences 14, 1261-1283, doi: 10.5194/bg-14-1261-2017, 2017. 19. Schirrmeister, L., Kunitsky, V.V., Grosse, G., Schwamborn, G., Andreev, A.A., Meyer, H., Kuznetsova, T., Bobrov, A., and Oezen, D.: Late Quaternary history of the accumulation plain north of the Chekanovsky Ridge (Lena Delta, Russia) - a multidisciplinary approach, Polar Geography, 27(4), 277-319, doi: 10.1080/789610225, 2003. 20. Schirrmeister, L., Grosse, G. Schnelle, M., Fuchs, M., Krbetschek, M., Ulrich, M., Kunitsky, V., Grigoriev, M., Andreev, A. Kienast, F., Meyer, H., Klimova, I., Babiy, O., Bobrov, A., Wetterich, S., and Schwamborn, G.: Late Quaternary paleoenvironmental records from the western Lena Delta, Arctic Siberia, Palaeogeography, Palaeoclimatology, Palaeoecology 299, 175–196, doi: 10.1016/j.quascirev.2009.11.017, 2011. 21. Schwamborn, G., Rachold, V., and Grigoriev, M.N.: Late Quaternary sedimentation history of the Lena Delta, Quaternary International 89, 119–134, doi: 10.1016/S1040-6182(01)00084-2, 2002. 22. Wetterich, S., Kuzmina, S., Andreev, A.A., Kienast, F., Meyer, H., Schirrmeister, L., Kuznetsova, T., and Sierralta, M.: Palaeoenvironmental dynamics inferred from late Quaternary permafrost deposits on Kurungnakh Island, Lena Delta, Northeast Siberia, Russia, Quaternary Science Reviews, 27, 1523-1540, doi: 10.1016/j.quascirev.2008.04.007, 2008. 23. Andreev, A.A., Grosse, G., Schirrmeister, L., Kuzmina, S.A., Novenko, E.Yu., Bobrov, A.A., Tarasov, P. E., Kuznetsova, T.V., Krbetschek, M., Meyer, H., and Kunitsky, V.V.: Late Saalian and Eemian palaeoenvironmental history of the Bol'shoy Lyakhovsky Island (Laptev Sea region, Arctic Siberia), Boreas 33(4), 319-348, doi:10.1080/03009480410001974, 2004. 24. Andreev, A., Grosse, G., Schirrmeister, L., Kuznetsova, T.V., Kuzmina, S.A., Bobrov, A.A., Tarasov, P.E., Novenko, E.Yu., Meyer, H., Derevyagin, A.Yu., Kienast, F., Bryantseva, A., and Kunitsky, V.V.: Weichselian and Holocene palaeoenvironmental history of the Bol’shoy Lyakhovsky Island, New Siberian Archipelago, Arctic Siberia, Boreas 38(1), 72–110, doi: 10.1111/j.1502-3885.2008.00039.x, 2009. 25. Wetterich, S., Rudaya, N., Meyer, H., Opel, T., and Schirrmeister, L.: Last Glacial Maximum records in permafrost of the East Siberian Arctic, Quaternary Science Reviews 30, 3139-3151, doi: 10.1016/j.quascirev.2011.07.020, 2011. 26. Wetterich, S., Rudaya, N., Andreev, A.A., Opel, T., Schirrmeister, L., Meyer, H., and Tumskoy, V.: Ice Complex formation in arctic East Siberia during the MIS3 Interstadial, Quaternary Science Reviews 84: 39-55, doi:. 10.1016/j.quascirev.2013.11.009, 2014. 27. Wetterich, S.; Tumskoy:V.E., Rudaya, N., Kuznetsov, V., Maksimov, F., Opel T. , Meyer H., Andreev, A.A., Schirrmeister, L (2016) Ice Complex permafrost of MIS5 age in the Dmitry Laptev Strait coastal region (East Siberian Arctic). Quaternary Science Reviews, 147:298-31, doi.org/10.1016/j.quascirev.2015.11.016. 28. Wetterich, S., Rudaya, N., Kuznetsov V., Maksimov, F., T. Opel, Meyer, H., Guenther, F., Bobrov, A., Raschke, E., Zimmermann, H., Strauss, J., Fuchs, M.C., Schirrmeister, L. (2019) Recurrent Ice Complex formation in arctic eastern Siberia since about 200 ka. Quaternary Research 92 (2); 530-548, doi.org/10.1017/qua.2019.6. 29. Wetterich, S., Schirrmeister, L., Andreev A. A., Pudenz, M., Plessen, B, Meyer, H., Kunitsky, V. V. (2009). Eemian and Late Glacial/Holocene palaeoenvironmental records from permafrost sequences at the Dmitry Laptev Strait (NE Siberia, Russia), Palaeogeography, Palaeoclimatology, Palaeoecology 279: 73-95 doi:10.1016/j.palaeo.2009.05.002. 30. Strauss, J., Schirrmeister, L., Wetterich, S., Borchers, A, and Davydov S.P.: Grain-size properties and organic-carbon stock of Yedoma Ice Complex permafrost from the Kolyma lowland, northeastern Siberia. GBC. 26: GB3003, doi: 10.1029/2011GB004104, 2012. 31. Ashastina, K., Schirrmeister, L., Fuchs M., and Kienast F.: Palaeoclimate characteristics in interior Siberia of MIS 6–2: first insights from the Batagay permafrost mega-thaw slump in the Yana Highlands, Clim. Past, 13, 795–818, doi: 10.5194/cp-13-795-2017, 2017. 32. Kunitsky, V.V., Syromyatnikov, I.I., Schirrmeister, L., Skachkov, Yu.B., Grosse, G., Wetterich, S., and Grigoriev, M.N.: Ice-rich permafrost and thermal denudation in the Kirgillyakh area, Kriosfera Zemli. 17(1), 56-68, 2013 (in Russian). 33. Popp, S., Diekmann,B., Meyer, H., Siegert, C.,Syromyatnikov, I., Hubberten, H.-W. Palaeoclimate Signals as Inferred from Stable-isotope Composition of Ground Ice in the Verkhoyansk Foreland, Central Yakutia. Permafrost and Periglac. Process. 17: 119–132 (2006) DOI: 10.1002/ppp.556 34. Popp, S., Belolyubsky, I., Lehmkuhl, F., Prokopiev, A., Siegert, C., Spektor, V., Stauch, G., Diekmann,B. Sediment provenance of late Quaternary morainic, fluvialand loess-like deposits in the southwestern VerkhoyanskMountains (eastern Siberia) and implications for regionalpalaeoenvironmental reconstructions. Geol. J.42: 477–497 (2007), DOI: 10.1002/gj.1088 35. Siegert, C. , Sergeyenko, A. I. and Schirrmeister, L. (2017) Late Quaternary Deposits of the Northern Verkhoyansk Mountains: Geochronology and Questions of their Genesis (in Russian), Bulletin of the Commission for Study of the Quaternary = БЮЛЛЕТЕНЬ КОМИССИИ ПО ИЗУЧЕНИЮ ЧЕТВЕРТИЧНОГО ПЕРИОДА, 75 , pp. 100-112 . 36. Siegert, C. , Stauch, G. , Lehmkuhl, F. , Sergeyenko, A. I. , Diekmann, B. , Popp, S. and Belolyubsky, I. N. (2007) Development of glaciation in the Verkhoyansk Range and its foreland during the Pleistocene: Results of new investigations., Regionalnaya Geologiya i Metallogeniya (Regional Geology and Metallogeny), No. 30-31(in Russian)., 222 . 37. Ulrich, M., Morgenstern, A., Günther, F., Reiss, D. Bauch, K. E., Hauber, E., Rössler, S. and Schirrmeister, L. (2010) Thermokarst in Siberian ice-rich permafrost: Comparison to asymmetric scalloped depressions on Mars, Journal of Geophysical Research, 115, E10009 . doi:10.1029/2010JE003640 , 38. Morgenstern, A. , Grosse, G. , Günther, F. , Fedorova, I. and Schirrmeister, L. (2011): Spatial analyses of thermokarst lakes and basins in Yedoma landscapes of the Lena Delta. The Cryosphere, 5(4), 849–867, doi:10.5194/tc-5-849-2011. 39. Morgenstern, A. , Ulrich, M. , Günther, F. , Roessler, S. , Fedorova, I. V. , Rudaya, N. A. , Wetterich, S. , Boike, J. and Schirrmeister, L. (2013). Evolution of thermokarst in East Siberian ice-rich permafrost: A case study, Geomorphology, 201 , 363-379. doi:10.1016/j.geomorph.2013.07.011 40. Biskaborn, B. , Herzschuh, U. , Bolshiyanov, D. Y. , Schwamborn, G. and Diekmann, B. (2013) Thermokarst Processes and Depositional Events in a Tundra Lake, Northeastern Siberia, Permafrost and Periglac. Process.24: 160–174 doi:https://doi.org/10.1002/ppp.1769, 41. Kuznetsova, T. V. , Sulerzhitsky, L. D. , Andreev, A. , Siegert, C. , Schirrmeister, L. and Hubberten, H. W. (2003) Influence of Late Quaternary paleoenvironmental conditions on the distribution of mammals fauna in the Laptev Sea region , Occasional Papers in Earth Sciences, 5 , pp. 58-60 . 42. Kuznetsova T.V., Tumskoy V.E., Schirrmeister L., Wetterich S., (2019.) Paleozoological characteristics of the Late Neo-Pleistocene - Holocene sediments of Bykovsky Peninsula, Northern Yakutia (Палеозоологическая характеристика поздненеоплейстоценовых – голоценовых отложений Быковского Полуострова (Северная Якутия). Zoological Journal 98(11), 1268-1290. Special issue in honor of Andrey Sher. (in Russian) doi: 10.1134/S0044513419110102. 43. Bobrov, A. A. , Andreev, A. , Schirrmeister, L. and Siegert, C. (2004) Testate amoebae (Protozoa: Testacea) as bioindicators in the Late Quaternary deposits of the Bykovsky Peninsula, Laptev Sea, Russia , Palaeogeography palaeoclimatology palaeoecology, 209 , pp. 165-181 . doi:https://doi.org/10.1016/J.PALAEO.2004.02.012 44. Wetterich, S., Schirrmeister, L., Pietrzeniuk, E. (2005). Freshwater ostracodes in Quaternary permafrost deposits from the Siberian Arctic, Journal of Paleolimnology, 34, 363-376. doi:10.1007/s10933-005-5801-y 45. Müller, S., Bobrov, A. A., Schirrmeister, L., Andreev, A. A., Tarasov, P. E. (2009). Testate amoebae record from the Laptev Sea coast and its implication for the reconstruction of Late Pleistocene and Holocene environments in the Arctic Siberia, Palaeogeography, Palaeoclimatology, Palaeoecology 271(3-4), 301-315. doi:10.1016/j.palaeo.2008.11.003 46. Andreev, A.A., Schirrmeister, L., Siegert, C., Bobrov, A.A., Demske, D., Seiffert, M., Hubberten, H.-W. (2002). Paleoenvironmental changes in Northeastern Siberia during the Late Quaternary - evidence from pollen records of the Bykovsky Peninsula, Polarforschung, 70, 13-25, doi:10.2312/polarforschung.70.13. 47. Andreev, A.A.; Schirrmeister, L.; Tarasov , P.E.; Ganopolski , A.; Brovkin V.; Siegert, C.; Hubberten, H.-W. (2011). Vegetation and climate history in the Laptev Sea region (arctic Siberia) during Late Quaternary inferred from pollen records. Journal of Quaternary science reviews. 30, 2182-2199 doi:10.1016/j.quascirev.2010.12.026. 48. Kienast, F. , Schirrmeister, L. , Siegert, C. and Tarasov, P. (2005) Palaeobotanical evidence for warm summers in the East Siberian Arctic during the last cold stage, Quaternary Research, 63 (3), pp. 283-300. doi:https://doi.org/10.1016/j.yqres.2005.01.003 , 49. Kienast, F., Tarasov, P., Schirrmeister, L., Grosse, G., Andreev, A.A. (2008). Continental climate in the East Siberian Arctic during the last interglacial: implications from palaeobotanical records, Global and Planetary Change, 60(3/4), 535-562. doi:10.1016/j.gloplacha.2007.07.004 50. Kienast, F., Wetterich, S., Kuzmina, S., Schirrmeister, L., Andrev, A., Tarasov, P., Nazarova, L., Kossler, A., Frolova, A., Kunitsky, V. V.(2011) Paleontological records indicate the occurrence of open woodlands in a dry inland climate at the present-day Arctic coast in western Beringia during the last interglacial. Quaternary Science Reviews 30: 2134-2159, doi:10.1016/j.quascirev.2010.11.024. 51. Palagushkina, O.V., Wetterich, S., Schirrmeister, L., Nazarova, L.B. (2017) Modern and fossil diatom assemblages from Bol'shoy Lyakhovsky Island (New Siberian Archipelago, Arctic Siberia). Contemporary Problems of Ecology, 10, (4), 380–394. doi: 10.1134/S1995425517040060. 52. Gilichinsky, D. A. , Nolte, E., Basilyan, A.E., Beer, J., Blinov, A., Lazarev, V., Kholodov, A., Meyer, H., Nikolsky, P.A., Schirrmeister, L., Tumskoy, V. (2007). Dating of syngenetic ice wedges in permafrost with 36Cl and 10Be, Quaternary science reviews. 26, 1547-1556. doi:10.1016/j.quascirev.2007.04.004 53. Blinov A.V., Beer J., Tikhomirov D.A., Schirrmeister L., Meyer H., Abramov A.A., Basylyan A.E., Nikolskiy P.A., Tumskoy V.E., Kholodov A.L., Gilichinsky D.A. (2009) Permafrost dating with the cosmogenic radionuclides ( Report 1) (= Датирование многолетнемерзлых пород с помощью космогенных радионуклидов (сообщение 1). Kriosfera Zemli 13,( 2), 3-15 (in Russian). 54. Blinov, A., Alfimov, V., Beer, J., Gilichinsky, D., Schirrmeister, L., Kholodov, A., Nikolskiy, P., Opel, T., Tikhomirov, D., Wetterich, S.(2009).36Cl/Cl ratio in ground ice of East Siberia and its application for chronometry, Geochemistry, Geophysics, Geosystems (G3). 10(1), doi: 10.1029/2009GC002548. 55. Schirrmeister, L., Oezen, D., Geyh, M.A. (2002). 230Th/U dating of frozen peat, Bol'shoy Lyakhovsky Island (North Siberia), Quaternary research, 57, 253-258. doi:10.1006/qres.2001.2306. 56. Meyer, H. , Derevyagin, A. Y. , Siegert, C. and Hubberten, H. W. (2002) Paleoclimate studies on Bykovsky Peninsula, North Siberia - hydrogen and oxygen isotopes in ground ice , Polarforschung 70:, pp. 37-51 . 57. Derevyagin, A. Y., Chizhov, A. , Meyer, H. , Opel, T. , Schirrmeister, L. and Wetterich, S. (2013). Isotopic composition of texture ices, Laptev Sea coast , Kriosfera Zemlii (Earth Cryosphere), XVII (3), pp. 27-34 (in Russian). 58. Meyer, H. , Derevyagin, A. Y. , Siegert, C. , Schirrmeister, L. and Hubberten, H. W. (2002) Paleoclimate reconstruction on Big Lyakhovsky Island, North Siberia - Hydrogen and oxygen isotopes in ice wedges , Permafrost and periglacial processes, 13 , pp. 91-105 . 59. Opel, T., Dereviagin, A., Meyer, H., Schirrmeister, L., Wetterich, S. (2010).Paleoclimatic information from stable water isotopes of Holocene ice wedges at the Dmitrii Laptev Strait (Northeast Siberia), Permafrost and Periglacial Processes. 22 (1), 84-100, doi:10.1002/ppp.667. 60. Opel, T., Wetterich, S., Meyer, H., Dereviagin, A.Yu., Fuchs, M.C., and Schirrmeister, L.: Ground-ice stable isotopes and cryostratigraphy reflect late Quaternary palaeoclimate in the Northeast Siberian Arctic (Oyogos Yar coast, Dmitry Laptev Strait). Clim. Past, 13, 587–611, 2017, doi: 10.5194/cp-13-587-2017, 2017. 61. Opel, T., Murton, J. B., Wetterich, S., Meyer, H., Ashastina, K., Günther, F., Grotheer, H., Mollenhauer, G., Danilov, P. P., Boeskorov, V., Savvinov, G. N., Schirrmeister, L. (2019) Past climate and continentality inferred from ice wedges at Batagay megaslump in the Northern Hemisphere's most continental region, Yana Highlands, interior Yakutia, Clim. Past, 15, 1443–1461, doi: 10.5194/cp-15-1443-2019. 62. Ulrich, M., Grosse, G., Strauss, J. and Schirrmeister, L. (2014): Quantifying wedge-ice volumes in yedoma and thermokarst basin deposits, Permafrost and Periglacial Processes 25, 151–161. doi:10.1002/ppp.1810. 63. Grosse, G., Schirrmeister, L., Siegert, C., Kunitsky, V.V., Slagoda, E.A., Andreev, A.A., and Dereviagyn, A.Y.: Geological and geomorphological evolution of a sedimentary periglacial landscape in Northeast Siberia during the Late Quaternary, Geomorphology, 86(1/2), 25-51, doi:10.1016/j.geomorph.2006.08.005, 2007. 64. Grosse, G., Schirrmeister, L., Kunitsky, V. V., Hubberten, H. -W. (2005). The Use of CORONA Images in Remote Sensing of Periglacial Geomorphology: An Illustration from the NE Siberian Coast, Permafrost and periglacial processes, 16, 163-172. doi:10.1002/ppp.509 65. Grosse, G., Robinson, J.E., Bryant, R., Taylor, M.D., Harper, W., DeMasi, A., Kyker-Snowman, E., Veremeeva, A., Schirrmeister, L., Harden, J. (2013). Distribution of late Pleistocene ice-rich syngenetic permafrost of the Yedoma Suite in east and central Siberia, Russia. U.S. Geological Survey Open File Report 2013-1078, 37p. 66. Schennen, S., Tronicke, J., Wetterich, S., Allroggen, N., Schwamborn, G., Schirrmeister, L. (2016) 3D GPR imaging of Ice Complex deposits in northern East Siberia, Geophysics 81(1), WA185-WA192, doi: 10.1190/GEO2015-0129.1. 67. Günther, F. , Overduin, P. P. , Yakshina, I. A. , Opel, T. , Baranskaya, A. V. and Grigoriev, M. N. (2015) Observing Muostakh disappear: permafrost thaw subsidence and erosion of a ground-ice-rich island in response to arctic summer warming and sea ice reduction , The Cryosphere, 9 (1), pp. 151-178 . doi.org/10.5194/tc-9-151-2015 68. Günther, F. , Overduin, P. P. , Sandakov, A. V. , Grosse, G. and Grigoriev, M. N. (2013) Short- and long-term thermo-erosion of ice-rich permafrost coasts in the Laptev Sea region, Biogeosciences, 10 , pp. 4297-4318 . doi:https://doi.org/10.5194/bg-10-4297-2013 69. Overduin, P. P. , Strzelecki, M. C. , Grigoriev, M. N. , Couture, N. , Lantuit, H. , St-Hilaire-Gravel, D. , Günther, F. and Wetterich, S. (2013) Coastal changes in the Arctic, Geological Society of London Special Publication, 388 . doi:https://doi.org/10.1144/SP388.13 70. Strauss J., Schirrmeister L., Grosse G., Wetterich S., Ulrich M., Herzschuh U., H.-W.Hubberten (2013). The Deep Permafrost Carbon Pool of the Yedoma Region in Siberia and Alaska. GRL 40, 6165-6170. doi 10.1002/2013GL058088. 71. Strauss, J., Schirrmeister, L., Mangelsdorf, K., Eichhorn, L., Wetterich S., and Herzschuh U.: Organic matter quality of deep permafrost carbon - a study from Arctic Siberia. Biogeosciences, 12, 2227–2245, doi: 10.5194/bg-12-2227-2015, 2015. 72. Strauss,J., Schirrmeister, L., Grosse, G., Fortier, D., Hugelius, G., Knoblauch, C., Romanovsky, V., Schädel, C., Schneider von Deimling, T., Schuur, E.A.G., Shmelev, D., Ulrich, M.,, Veremeeva, A. (2017). Deep Yedoma permafrost: A synthesis of depositional characteristics and carbon vulnerability. Earth-Science Reviews 172, 75-86, doi: 10.1016/j.earscirev.2017.07.007. 73. Stapel, J. G., L. Schirrmeister, P. P. Overduin, S. Wetterich, J. Strauss, B. Horsfield, and K. Mangelsdorf (2016), Microbial lipid signatures and substrate potential of organic matter in permafrost deposits - implications for future greenhouse gas production, J. Geophys. Res. Biogeosci., 121, doi: 10.1002/2016JG003483. 74. Stapel, J.G, Schwamborn, G., Schirrmeister, L., Horsfield, B. and Mangelsdorf, K. (2018) Substrate potential of last interglacial to Holocene permafrost organic matter for future microbial greenhouse gas production. Biogeosciences, 15, 1969–1985, doi: 10.5194/bg-15-5423-2018. 75. Walz, J., Knoblauch, C., Tigges, R., Opel, T., Schirrmeister, L., and Pfeiffer, E.-M. (2018) Greenhouse gas production in degrading ice-rich permafrost deposits in northeast Siberia. Biogeosciences, 15, 5423–5436, doi: 10.5194/bg-2018-225. 76. Fuchs, M. , Grosse, G. , Strauss, J. , Günther, F. , Grigoriev, M. N. , Maximov, G. M. and Hugelius, G. (2018) Carbon and nitrogen pools in thermokarst-affected permafrost landscapes in Arctic Siberia , Biogeosciences, 15 , pp. 953-971 . 77. Kusch, S., Winterfeld, M., Mollenhauer, G., Höfle, S.T., Schirrmeister, L., Schwamborn, G., and Rethemeyer, J. (2019) Glycerol dialkyl glycerol tetraethers (GDGTs) in high latitude Siberian permafrost: Diversity, environmental controls, and implications for proxy applications. Organic Geochemistry 136, 103888, doi: 10.1016/j.orggeochem.2019.06.009. 78. Mitzscherling, J., Horn, F., Winterfeld, M., Mahler, L., Kallmeyer, J., Overduin, P.P., Schirrmeister, L., Winkel, M., Grigoriev, M.N., Wagner, D., Liebner, S. (2019) (6bial community composition and abundance after millennia of submarine permafrost warming. Biogeosciences, 16, 3941–3958, doi: 10.5194/bg-16-3941-2019. 79. Zimmermann, H.H., Raschke, E., Epp, L.S., Stoof-Leichsenring, K.R., Schirrmeister, L., Schwamborn, G., Herzschuh, U. (2017). The history of tree and shrub taxa on Bol’shoy Lyakhovsky Island (New Siberian Archipelago) since the last interglacial uncovered by sedimentary ancient DNA and pollen data. Genes 8(10), E273; doi: 10.3390/genes8100273. 80. Zimmermann, H.H., Raschke, E., Epp, L.S., Stoof-Leichsenring, K., Schwamborn, G., Schirrmeister, L., Overduin, P.P., Herzschuh, U. (2017) Sedimentary ancient DNA and pollen reveal the composition of plant organic matter in Late Quaternary permafrost sediments of the Buor Khaya Peninsula (north-eastern Siberia). Biogeosciences 14, 575-596, doi:10.5194/bg-14-575-2017

Published
2020

4. Mineral associations of late Quaternary permafrost deposits - Bol’shoy Lyakhovsky Island compared to other locations in northern Siberia

Author

Schirrmeister, Lutz, Wetterich, Sebastian, Schwamborn, Georg, Matthes, Heidrun, Grosse, Guido, Klimova, I., Kunitsky, Viktor V., and Siegert, Christine

Abstract

Bol’shoy Lyakhovsky Island has been a major focus area in Yedoma research in course of joint Russian-German expeditions in 1999, 2007 and 2014 conducted by colleagues from the Mel’nikov Permafrost Institute Yakutsk and the Alfred Wegener Institute Potsdam [1,2]. However, origins and genesis of periglacial deposits such as the late Pleistocene Yedoma Ice Complex are still debated [3] and referred to by some researchers as pure windblown sediments, while other researchers suggest more local sediment sources from intense nivation and periglacial weathering, or even a polygenetic origin under comparable cold-climatic, highly continental conditions in different regions. To disentangle sources and potential transport pathways of sediments, mineral associations are useful indicators. Identifying linkages of mineral associations in sediments to local bedrock, fluvial sources, or fare ranging sources for potential eolian transport are therefore important. Various studies on palaeoecology [4,5], stable isotopy [6], geophysics [7], biogeochemistry [8] and palaeogenetics [9] have been carried out over the last more than 20 years. In the present study, we analyzed the mineral associations in sediments of one of the best-dated permafrost sequences including the Yedoma Ice Complex exposed at the southern coast of Bol’shoy Lyakhovsky Island near the Zimov’e River mouth. The permafrost record spans about 200 ka covering the Marine Isotope Stages (MIS) 6 to MIS 1 [10,11,12,13,15], although not continuously. From these deposits, exposed from sea level to about 35 m above sea level, we studied heavy and light minerals of 65 samples from different cryostratigraphic horizons in both the 63-125 µm and the 125-250 µm fractions. The studied mineral grains used are subangular to slightly rounded. The heavy mineral associations are dominated by amphibole, epidote, pyroxene, titanite, ilmenite, garnet, zircon, apatite, and rutile. Leucoxene is found in several samples as well as biotite, chlorite and weathered micas. The light mineral association is dominated by feldspar, quartz, and chlorites. Carbonates, muscovite, and broken mica are observed in some samples. Differences in the heavy and light mineral associations represent varying sediment sources and transport mechanisms of the deposits aligned to the distinct cryostratigraphic horizons (Fig. 1). Characteristic associations of the different horizons are assessed using variance analysis on the counted mineral grains. Statistically significant (at 95% confidence level) distinct mineral associations are found with ilmenite, garnet, zircon, tourmaline, titanite, and leucoxene in the heavy minerals and feldspar in the light minerals. MIS 1 (Holocene thermokarst deposits) is the least distinctly separable unit in the heavy minerals, MIS 4 (Zyryan stadial floodplain deposits) and MIS 6 (Yukagir interstadial Ice Complex) are the most distinctly separable units. In the light minerals, MIS 2 (stadial Sartan Yedoma Ice Complex) is the least and MIS 4 the most distinctly separable unit. The MIS 3 (interstadial Molotkov Yedoma Ice Complex) and the MIS 5 (interglacial Kazantsev thermokarst deposits) units show intermediate separability in both heavy and light minerals. The Bol’shoy Lyakhovsky mineral associations were compared with other permafrost exposures on the Siberian mainland along the Laptev Sea coast [15,16,17], in the Lena Delta [18], and on other islands of the New Siberian Archipelago. Our findings suggest that weathered bedrock from nearby ridges and hills was the most likely source material for the formation of late Quaternary permafrost deposits. The local sediment sources are more in line with hypotheses for Yedoma Ice Complex genesis [19] that involve largely local erosion, transport, and deposition processes as opposed to eolian deposition involving regional to panarctic-scale movement of dust and larger grainsize particles. A B Fig. 1 Averages of heavy (A) and light (B) mineral associations of the 63-125 µm fraction according to the stratigraphy References 1. Andreev, A. et al. Weichselian and Holocene palaeoenvironmental history of the Bol’shoy Lyakhovsky Island, New Siberian Archipelago, Arctic Siberia, Boreas, 2009, 38(1), 72–110. 2. Andreev, A. et al. Late Saalian and Eemian palaeoenvironmental history of the Bol'shoy Lyakhovsky Island (Laptev Sea region, Arctic Siberia), Boreas, 2004, 33(4), 319-348. 3. Schirrmeister, L. et al. Yedoma: Late Pleistocene ice-rich syngenetic permafrost of Beringia, Encyclopedia of Quaternary Science, 2nd edition, 2013, 3, 542-552. 4. Kienast, F. et al. Continental climate in the East Siberian Arctic during the last interglacial: implications from palaeobotanical records, Global Planet. Change, 2008, 60(3/4), 535-562. 5. Sher, A.V. et al. New insights into the Weichselian environment and climate of the East Siberian Arctic, derived from fossil insects, plants, and mammals, Quat. Sci. Rev., 2005, 24, 533–569. 6. Meyer, H. et al. Paleoclimate reconstruction on Big Lyakhovsky Island, North Siberia - Hydrogen and oxygen isotopes in ice wedges, Permafrost Periglac. Process., 2002, 1, 91–105. 7. Schennen, S. et al. 3D GPR imaging of Ice Complex deposits in northern East Siberia, Geophysics, 2016, 81(1), WA185-WA192 8. Stapel, J.G. et al. Substrate potential of last interglacial to Holocene permafrost organic matter for future microbial greenhouse gas production, Biogeosciences, 2018, 15, 1969–1985. 9. Zimmermann, H.H. et al. The history of tree and shrub taxa on Bol’shoy Lyakhovsky Island (New Siberian Archipelago) since the last interglacial uncovered by sedimentary ancient DNA and pollen data, Genes, 2017, 8(10), E273 10. Wetterich, S. et al. Eemian and Late Glacial/Holocene palaeoenvironmental records from permafrost sequences at the Dmitry Laptev Strait (NE Siberia, Russia), Palaeogeogr. Palaeoclimatol. Palaeoecol., 2009, 27, 73-95. 11. Wetterich, S. et al. Last Glacial Maximum records in permafrost of the East Siberian Arctic, Quat. Sci. Rev., 2011, 30, 3139-3151. 12. Wetterich, S. et al. Ice Complex formation in arctic East Siberia during the MIS3 Interstadial, Quat. Sci. Rev., 2014, 84: 39-55. 13. Wetterich, S. et al. Ice Complex permafrost of MIS5 age in the Dmitry Laptev Strait coastal region (East Siberian Arctic), Quat. Sci. Rev., 2016, 147: 298-31 14. Wetterich, S. et al. Recurrent Ice Complex formation in arctic eastern Siberia since about 200 ka, Quat. Res., 2019, 92(2): 530-548. 15. Siegert, C. et al. The sedimentological, mineralogical and geochemical composition of late Pleistocene deposits from the ice complex on the Bykovsky peninsula, northern Siberia, Polarforschung, 2000, 70, 3-11. 16. Schirrmeister, L. et al. Paleoenvironmental and paleoclimatic records from permafrost deposits in the Arctic region of Northern Siberia, Quat. Int., 2002, 89, 97-118. 17. Schirrmeister, L. et al. Periglacial landscape evolution and environmental changes of Arctic lowland areas for the last 60,000 years (Western Laptev Sea coast, Cape Mamontov Klyk), Polar Research, 2008, 27(2), 249-272. 18. Schirrmeister; L. et al. ). Late Quaternary paleoenvironmental records from the western Lena Delta, Arctic Siberia, Palaeogeogr. Palaeoclimatol. Palaeoecol., 2011, 299, 175–196 19. Schirrmeister, L. et al. The genesis of Yedoma Ice Complex permafrost – grain-size endmember modeling analysis from Siberia and Alaska, E&G Quaternary Sci. J., 2020, 69, 33–53

Published
2020

5. Circum-Arctic Map of the Yedoma Permafrost Domain

Author

Strauss, Jens, Laboor, Sebastian, Schirrmeister, Lutz, Fedorov, Alexander N., Fortier, Daniel, Froese, Duane, Fuchs, Matthias, Günther, Frank, Grigoriev, Mikhail N., Harden, Jennifer, Hugelius, Gustaf, Jongejans, Loeka L., Kanevskiy, Mikhail, Kholodov, A. L., Kunitsky, Viktor V., Kraev, Gleb, Lozhkin, Anatoly V., Rivkina, Elizaveta, Shur, Yuri, Siegert, Christine, Spektor, Valentin V., Streletskaya, Irina D., Ulrich, Mathias, Vartanyan, Sergey, Veremeeva, Aleksandra A., Walter Anthony, Katey M., Wetterich, Sebastian, Zimov, Nikita, Grosse, Guido, Strauss, Jens, Laboor, Sebastian, Schirrmeister, Lutz, Fedorov, Alexander N., Fortier, Daniel, Froese, Duane, Fuchs, Matthias, Günther, Frank, Grigoriev, Mikhail N., Harden, Jennifer, Hugelius, Gustaf, Jongejans, Loeka L., Kanevskiy, Mikhail, Kholodov, A. L., Kunitsky, Viktor V., Kraev, Gleb, Lozhkin, Anatoly V., Rivkina, Elizaveta, Shur, Yuri, Siegert, Christine, Spektor, Valentin V., Streletskaya, Irina D., Ulrich, Mathias, Vartanyan, Sergey, Veremeeva, Aleksandra A., Walter Anthony, Katey M., Wetterich, Sebastian, Zimov, Nikita, and Grosse, Guido

Abstract

Ice-rich permafrost in the circum-Arctic and sub-Arctic (hereafter pan-Arctic), such as late Pleistocene Yedoma, are especially prone to degradation due to climate change or human activity. When Yedoma deposits thaw, large amounts of frozen organic matter and biogeochemically relevant elements return into current biogeochemical cycles. This mobilization of elements has local and global implications: increased thaw in thermokarst or thermal erosion settings enhances greenhouse gas fluxes from permafrost regions. In addition, this ice-rich ground is of special concern for infrastructure stability as the terrain surface settles along with thawing. Finally, understanding the distribution of the Yedoma domain area provides a window into the Pleistocene past and allows reconstruction of Ice Age environmental conditions and past mammoth-steppe landscapes. Therefore, a detailed assessment of the current pan-Arctic Yedoma coverage is of importance to estimate its potential contribution to permafrost-climate feedbacks, assess infrastructure vulnerabilities, and understand past environmental and permafrost dynamics. Building on previous mapping efforts, the objective of this paper is to compile the first digital pan-Arctic Yedoma map and spatial database of Yedoma coverage. Therefore, we 1) synthesized, analyzed, and digitized geological and stratigraphical maps allowing identification of Yedoma occurrence at all available scales, and 2) compiled field data and expert knowledge for creating Yedoma map confidence classes. We used GIS-techniques to vectorize maps and harmonize site information based on expert knowledge. We included a range of attributes for Yedoma areas based on lithological and stratigraphic information from the source maps and assigned three different confidence levels of the presence of Yedoma (confirmed, likely, or uncertain). Using a spatial buffer of 20 km around mapped Yedoma occurrences, we derived an extent of the Yedoma domain. Our result is a vector-b

Published
2021

7. Organic Matter Matters – Quantifying the Amount of Carbon in Northern Siberia

Author

Hubberten, Hans-Wolfgang, Bolshiyanov, Dmitry Yu., Grigoriev, Mikhail N., Grosse, Guido, Morgenstern, Anne, Pfeiffer, Eva-Maria, Rachold, Volker, Schirrmeister, Lutz, Strauss, Jens, Zubrzycki, Sebastian, Kholodov, Aleksander L., Kunitsky, Viktor V., Fuchs, Matthias, Hubberten, Hans-Wolfgang, Bolshiyanov, Dmitry Yu., Grigoriev, Mikhail N., Grosse, Guido, Morgenstern, Anne, Pfeiffer, Eva-Maria, Rachold, Volker, Schirrmeister, Lutz, Strauss, Jens, Zubrzycki, Sebastian, Kholodov, Aleksander L., Kunitsky, Viktor V., and Fuchs, Matthias

Abstract

The Lena River Delta is underlain by permafrost. Thus, it is highly vulnerable to climate warming and may degrade in different ways, by shoreline erosion, land surface subsidence, deepening of the seasonal thawing front, and development of rapid thaw features such as lakes, gullies and landslides.

Published
2018

8. Geocryological and Paleoenvironmental Studies on the Coasts of the Laptev Sea

Author

Hubberten, Hans-Wolfgang, Bolshiyanov, Dimitry Yu., Grigoriev, Mikhail N., Grosse, Guido, Morgenstern, Anne, Pfeiffer, Eva-Maria, Rachold, Volker, Schirrmeister, Lutz, Siegert, Christine, Meyer, Hanno, Kunitsky, Viktor V., Hubberten, Hans-Wolfgang, Bolshiyanov, Dimitry Yu., Grigoriev, Mikhail N., Grosse, Guido, Morgenstern, Anne, Pfeiffer, Eva-Maria, Rachold, Volker, Schirrmeister, Lutz, Siegert, Christine, Meyer, Hanno, and Kunitsky, Viktor V.

Published
2018

9. Kohlenstoff in Permafrost – Quantifizierung der Menge an organischem Material in Sibirien

Author

Hubberten, Hans-Wolfgang, Bolshiyanov, Dimitry Yu., Grigoriev, Mikhail N., Grosse, Guido, Morgenstern, Anne, Pfeiffer, Eva-Maria, Rachold, Volker, Schirrmeister, Lutz, Strauss, Jens, Zubrzycki, Sebastian, Kholodov, Aleksander L., Kunitsky, Viktor V., Fuchs, Matthias, Hubberten, Hans-Wolfgang, Bolshiyanov, Dimitry Yu., Grigoriev, Mikhail N., Grosse, Guido, Morgenstern, Anne, Pfeiffer, Eva-Maria, Rachold, Volker, Schirrmeister, Lutz, Strauss, Jens, Zubrzycki, Sebastian, Kholodov, Aleksander L., Kunitsky, Viktor V., and Fuchs, Matthias

Abstract

Permafrost in Sibirien taut, und das auf verschiedene Weise. Besonders gut sichtbar sind Küstenerosion und Bodenabsenkungen, oder wenn vorhandene Straßen, Häuser und andere Infrastruktur dadurch beschädigt wird. Doch auch eine Vertiefung der sommerlichen Auftauschicht und Entstehung von Seen, was zu schnellen Auftauprozessen (Thermokarst) führt, machen die Permafrostregion zu einer Region, in der der Klimawandel heute deutlich sichtbar wird.

Published
2018

10. Permafrost Deep Organic Matter: The IPA Yedoma Action Group

Author

Strauss, Jens, Fortier, Daniel, Froese, Duane, Grosse, Guido, Kanevskiy, Mikhail, Kunitsky, Viktor V., Laboor, Sebastian, Schirrmeister, Lutz, Shmelev, Denis, and Veremeeva, Alexandra

Abstract

Die Action Group "The Yedoma Region: A Synthesis of Circum-Arctic Distribution and Thickness" der Internationalen Permafrost Assoziation (IPA) hat es zum Ziel die Verbreitung und Mächtigkeit von Yedoma Permafrost, einem spätpleitozänen sehr eisreichem Permafrost, zu quantifizieren. Yedoma ist durch Eisgehalte von bis zu 80vol% sehr anfällig gegenüber Erwärmung. Denn wenn das Bodeneis schmilzt und abgeführt wird sind Absenkungen der Bodenoberflächen von mehr als 30 Metern möglich, was deutliche Auswirkungen hat auf die Landschaft, samt Infrastruktur und menschlicher Landnutzung. Als Produkt dieses Projektes möchten wir hier eine circum-arktische Karte präsentieren. Diese Daten werden als Grundlage dazu dienen, den Kohlenstoffpool von Yedoma Ablagerungen realistisch in computergestützte Modelle zu implementieren und die zukünftigen Auswirkungen von Thermokarst und Thermoerosion auf die Treibhausgasemissionen abzuschätzen.

Published
2017

11. Ice-Rich Yedoma Permafrost: Circum-Arctic Distribution and Thickness Synthesis

Author

Strauss, Jens, Fedorov, Alexander N., Fortier, Daniel, Froese, Duane, Fuchs, Matthias, Grosse, Guido, Günther, Frank, Harden, Jennifer, Hugelius, Gustaf, Kanevskiy, Mikhail, Kholodov, Alexander L., Kunitsky, Viktor V., Laboor, Sebastian, Lapointe-Elmrabti, Lyna, Rivkina, Elizaveta, Robinson, Joel, Schirrmeister, Lutz, Shmelev, Denis, Shur, Yuri, Spektor, Valentin V., Ulrich, Mathias, Veremeeva, Alexandra, Walter Anthony, Katey M., and Zimov, Sergei

Published
2016

12. Ice-Rich Yedoma Permafrost: A Synthesis of Circum-Arctic Distribution and Thickness

Author

Strauss, Jens, Fedorov, Alexander N., Fortier, Daniel, Froese, Duane, Fuchs, Matthias, Grosse, Guido, Günther, Frank, Harden, Jennifer W., Hugelius, Gustaf, Kanevskiy, Mikhail, Kholodov, Alexander L., Kunitsky, Viktor V., Laboor, Sebastian, Lapointe-Elmrabti, Lyna, Rivkina, Elizaveta, Robinson, Joel, Schirrmeister, Lutz, Shmelev, Denis, Shur, Yuri, Spektor, Valentin V., Ulrich, Mathias, Veremeeva, Alexandra, Walter Anthony, Katey M., and Zimov, Sergei

Abstract

Vast portions of Arctic and sub-Arctic Siberia, Alaska and the Yukon Territory are covered by ice-rich silts that are penetrated by large ice wedges, resulting from syngenetic sedimentation and freezing. Accompanied by wedge-ice growth, the sedimentation process was driven by cold continental climatic and environmental conditions in unglaciated regions during the late Pleistocene, inducing the accumulation of the unique Yedoma permafrost deposits up to 50 meter thick. Because of fast incorporation of organic material into permafrost during formation, Yedoma deposits include low-decomposed organic matter. Moreover, ice-rich permafrost deposits like Yedoma are especially prone to degradation triggered by climate changes or human activity. When Yedoma deposits degrade, large amounts of sequestered organic carbon as well as other nutrients are released and become part of active biogeochemical cycling. This could be of global significance for the climate warming, as increased permafrost thaw is likely to cause a positive feedback loop. Therefore, a detailed assessment of the Yedoma deposit volume is of importance to estimate its potential future climate response. Moreover, as a step beyond the objectives of this synthesis study, our coverage (see figure for the Yedoma domain) and thickness estimation will provide critical data to refine the Yedoma permafrost organic carbon inventory, which is assumed to have freeze-locked between 83±12 and 129±30 gigatonnes (Gt) of organic carbon. Hence, we here synthesize data on the circum-Arctic and sub-Arctic distribution and thickness of Yedoma permafrost (see figure for the Yedoma domain) in the framework of an Action Group funded by the International Permafrost Association (IPA). The quantification of the Yedoma coverage is conducted by the digitization of geomorphological and Quaternary geological maps. Further data on Yedoma thickness is contributed from boreholes and exposures reported in the scientific literature.

Published
2015

13. The Batagay mega thaw slump, Yana Uplands, Yakutia, Russia: permafrost thaw dynamics on decadal time scale

Author

Günther, Frank, Grosse, Guido, Wetterich, Sebastian, Jones, Benjamin M., Kunitsky, Viktor V., Kienast, Frank, and Schirrmeister, Lutz

Abstract

Ice-rich permafrost that formed in glacial periods of the Quaternary is highly vulnerable to thaw under ongoing climate change and anthropogenic disturbance. Permafrost degradation processes such as thermokarst, thermo-denudation and thermo-erosion are actively shaping modern periglacial landscapes. Retrogressive thaw slumps – also referred to as thermo-cirques – represent a highly dynamic geomorphologic feature in ice-rich permafrost regions. These rapidly forming landforms consist of a steep headwall surrounding a gently inclined slump floor where sediment erosion and accumulation takes place simulatenously and develop as a result of rapid permafrost thaw over several decades. Thaw slumps are commonly found in permafrost areas with near-surface, thick ground-ice layers that are susceptible to thermo-denudation and subsequent mass displacement through cryogenic landslides (Leibman et al., 2008). Thaw slumps are particularly frequent along riverbanks and coastlines in the Northwest American and West Siberian Arctic, where they are typically initiated by lateral erosion of the bluff toe. In these regions, buried glacier ice (massive ground ice) bodies or ice-rich glacial till have been mapped. Given their exceptional size of up to 40 ha in area and 25 m high headwalls, so-called mega slumps in northwestern Canada represent primary terrain destabilization features with different environmental settings than surrounding areas (Lantuit et al., 2012), but are a significant source for sediment and solute delivery to adjacent lakes and streams (Kokelj et al., 2013). However, in East Siberia, retrogressive thaw slumps have been described in the syngenetic Late Pleistocene Ice Complex (Yedoma) permafrost deposits, where massive ice wedges and segregated intrasedimentary ice results in total volumetric ice contents of up to 80-90%. Such retrogressive thaw slumps in syngenetic permafrost were investigated for example on the coastal area of the Dmitry Laptev Strait (Are et al., 2005). However, Yedoma deposits are also found on slopes of the Verkhoyan Mountain Range (Slagoda, 1991) and in valleys of surrounding foothills (Grosse et al., 2007) beyond the Yedoma main distributional range in the coastal lowlands of the Laptev and East Siberian seas. The Batagay mega slump is at least two times larger than any previously described thaw slump, has been discovered near the village of Batagay, and has been the subject of some recent cryostratigraphical analysis (Kunitsky et al 2013). It exposes a profile of Yedoma deposits, reaching a thickness of 7 to 22 m in that area (Slagoda, 1991) and underlying ice-rich periglacial alluvial sand deposits of around 60 m thickness (Kunitsky et al., 2013). The observed rapid development of thermo-denudation at rates of up to 15 m per year, poses the question of whether the larger portions of the entire region between the Verkhoyan and Cherskiy mountain ranges may be more vulnerable to deep and rapid thaw following disturbances such as forest fires or forest clearance. Using a set of historical remote sensing data, Kunitsky et al. (2013) suggest that depression-like structures on the Kirgillyakh-Khatyngnakhskoy Mountain saddle begin in the early 1970s. The initial disturbance causing rapid thermo-denudational development of the Batagay mega thaw slump started at the end of the 1980s. Here we present data from a remote sensing investigation of the mega slump (. in order to assess the planimetric dimensions and its recent expansion rates. We acquired very high resolution satellite imagery from QuickBird, IKONOS, KOMPSAT-2, WorldView-1 and WorldView-2, spanning a timeframe from 2006 to 2014. Aerotriangulation of the entire dataset was performed to ensure consistent co-registration between images. In addition, for terrain correction through ortho-rectification and for volumetric analyses of the entire mega slump, we derived an accurate digital elevation model (DEM) with 2m ground resolution from along and across track WorldView stereo imagery. The height difference between the headwall and the outflow of the slump into the Batagay river is 145 m along a distance of 2300m, while the slump maximum width is 800 m. Our analysis doesn’t show any signs of erosion slowdown along a headwall that is up to 86 m high. Comparison of the DEM with a reconstructed paleo-surface revealed that the slump has carved into the rolling topography to a depth of up to 73 m. The current size of the Batagay mega slump is >81 ha, while it had thawed >24.2 × 106 m³ of ice-rich permafrost through 2014. This huge amount of sediment released from the slump episodically dams up the Batagay river, forming a large temporary lake which then may discharge catastrophically. Geological on-site investigations and further geomorphometric analyses of this locality in conjunction with inter-annual and seasonal change detection observations will allow relating headwall retreat rates to local and regional controls on mega slump development and will help to identify potential areas susceptible to megaslump formation in non-glaciated regions. References Are, F.E., M.N. Grigoriev, H.-W. Hubberten, & V. Rachold (2005), Using thermoterrace dimensions to calculate the coastal erosion rate, Geo-Marine Letters, 25, 121-126. Grosse, G., L. Schirrmeister, C. Siegert, V.V. Kunitsky, E.A. Slagoda, A.A. Andreev & A.Y. Dereviagyn (2007), Geological and geomorphological evolution of a sedimentary periglacial landscape in Northeast Siberia during the Late Quaternary, Geomorphology, 89(1-2), 25-51. Kokelj, S.V., D. Lacelle, T.C. Lantz, J. Tunnicliffe, L. Malone, I.D. Clark & K.S. Chin (2013), Thawing of massive ground ice in mega slumps drives increases in stream sediment and solute flux across a range of watershed scales, Journal of Geophysical Research: Earth Surface, 118, 681-692. Kunitsky, V.V., I.I. Syromyatnikov, L. Schirrmeister, Yu.B. Skachkov, G. Grosse, S. Wetterich, & M.N. Grigoriev (2013), Ice-rich permafrost and thermal denudation in the Batagay area - Yana Upland, East Siberia, Kriosfera Zemli (Earth' Cryosphere), 17(1), 56-68. Lantuit, H., W.H. Pollard, N. Couture, M. Fritz, L. Schirrmeister, H. Meyer & H.-W. Hubberten (2012), Modern and Late Holocene Retrogressive Thaw Slump Activity on the Yukon Coastal Plain and Herschel Island, Yukon Territory, Canada, Permafrost and Periglacial Processes, 23(1), 39-51. Leibman, M., A. Gubarkov, A. Khomutov, A. Kizyakov & B. Vanshtein (2008), Coastal processes at the tabular-ground-ice-bearing area, Yugorsky Peninsula, Russia, in: Kane, D.L. and Hinkel, K.M. (eds), Proceedings of the Ninth International Conference on Permafrost, University of Alaska Fairbanks, June 29-July 3 2008, 1037-1042. Slagoda, E. A. (1991), Microstructure of permafrost slope deposits of the Kisilyakh Range, in: Melnikov, P.I. and Popov, A.I. (eds), Denudation in the cryolithozone, 19-29, Nauka, Moscow.

Published
2015

14. Ice-Rich Yedoma Permafrost: A Synthesis of Northern Hemisphere Distribution and Thickness (IPA Action Group)

Author

Strauss, Jens, Fedorov, Alexander N., Fortier, Daniel, Froese, Duane, Fuchs, Matthias, Grosse, Guido, Günther, Frank, Harden, Jennifer W., Hugelius, Gustaf, Kanevskiy, Mikhail, Kholodov, Aleksander L., Kunitsky, Viktor V., Kraev, Gleb, Laboor, Sebastian, Lapointe Elmrabti, Lyna, Lozhkin, Anatoly V., Rivkina, Elizaveta, Robinson, Joel, Schirrmeister, Lutz, Shmelev, Denis, Shur, Yuri, Siegert, Christine, Spektor, Valentin V., Ulrich, Mathias, Vartanyan, Sergey, Veremeeva, Alexandra, Walter Anthony, Katey M., Zimov, Sergei, Strauss, Jens, Fedorov, Alexander N., Fortier, Daniel, Froese, Duane, Fuchs, Matthias, Grosse, Guido, Günther, Frank, Harden, Jennifer W., Hugelius, Gustaf, Kanevskiy, Mikhail, Kholodov, Aleksander L., Kunitsky, Viktor V., Kraev, Gleb, Laboor, Sebastian, Lapointe Elmrabti, Lyna, Lozhkin, Anatoly V., Rivkina, Elizaveta, Robinson, Joel, Schirrmeister, Lutz, Shmelev, Denis, Shur, Yuri, Siegert, Christine, Spektor, Valentin V., Ulrich, Mathias, Vartanyan, Sergey, Veremeeva, Alexandra, Walter Anthony, Katey M., and Zimov, Sergei

Abstract

Vast portions of Arctic and sub-Arctic Siberia, Alaska and the Yukon Territory are covered by ice-rich silty to sandy deposits that are containing large ice wedges, resulting from syngenetic sedimentation and freezing. Accompanied by wedge-ice growth in polygonal landscapes, the sedimentation process was driven by cold continental climatic and environmental conditions in unglaciated regions during the late Pleistocene, inducing the accumulation of the unique Yedoma deposits up to >50 meters thick. Because of fast incorporation of organic material into syngenetic permafrost during its formation, Yedoma deposits include well-preserved organic matter. Ice-rich deposits like Yedoma are especially prone to degradation triggered by climate changes or human activity. When Yedoma deposits degrade, large amounts of sequestered organic carbon as well as other nutrients are released and become part of active biogeochemical cycling. This could be of global significance for future climate warming as increased permafrost thaw is likely to lead to a positive feedback through enhanced greenhouse gas fluxes. Therefore, a detailed assessment of the current Yedoma deposit coverage and its volume is of importance to estimate its potential response to future climate changes. We synthesized the map of the coverage (see figure) and thickness estimation, which will provide critical data needed for further research. In particular, this preliminary Yedoma map is a great step forward to understand the spatial heterogeneity of Yedoma deposits and its regional coverage. There will be further applications in the context of reconstructing paleo-environmental dynamics and past ecosystems like the mammoth-steppe-tundra, or ground ice distribution including future thermokarst vulnerability. Moreover, the map will be a crucial improvement of the data basis needed to refine the present-day Yedoma permafrost organic carbon inventory, which is assumed to be between 83±12 (Strauss et al., 2013) and 129±3

Published
2016

16. Dinamika beregov vostochnykh arkticheskikh morej Rossii: osnovnye faktory, zakonomernosti i tendentsii (Dynamics of the Russian east Arctic sea coast: Major factors, regularities and tendencies)

Author

Grigoriev, Mikhail N., Razumov, Sergey O., Kunitsky, Viktor V., and Spektor, V. B.

Abstract

Climatic, geocryological, geological and hydrodynamic conditions and available data on Arctic coast dynamics are analyzed. The basic laws of ice-rich coast development in varied geocryological and climatic conditions are investigated. Functional connections of coastal destructive cryogenic processes activity with summer air temperature and storms recurrence are revealed. The forecast of ice-rich coast rate retreat for the Laptev Sea and East-Siberian Sea is executed in connection with prospective changes of climate in XXI century.

Published
2006

17. Coastal permafrost landscape development since the Late Pleistocene in the western Laptev Sea, Siberia

Author

Winterfeld, Maria, Schirrmeister, Lutz, Grigoriev, Mikhail N., Kunitsky, Viktor V., Andreev, Andrei, Murray, Andrew, Overduin, Pier Paul, Winterfeld, Maria, Schirrmeister, Lutz, Grigoriev, Mikhail N., Kunitsky, Viktor V., Andreev, Andrei, Murray, Andrew, and Overduin, Pier Paul

Abstract

The palaeoenvironmental development of the western Laptev Sea is understood primarily from investigations of exposed cliffs and surface sediment cores from the shelf. In 2005, a core transect was drilled between the Taymyr Peninsula and the Lena Delta, an area that was part of the westernmost region of the non-glaciated Beringian landmass during the late Quaternary. The transect of five cores, one terrestrial and four marine, taken near Cape Mamontov Klyk reached 12km offshore and 77m below sea level. A multiproxy approach combined cryolithological, sedimentological, geochronological (C-14-AMS, OSL on quartz, IR-OSL on feldspars) and palaeoecological (pollen, diatoms) methods. Our interpretation of the proxies focuses on landscape history and the transition of terrestrial into subsea permafrost. Marine interglacial deposits overlain by relict terrestrial permafrost within the same offshore core were encountered in the western Laptev Sea. Moreover, the marine interglacial deposits lay unexpectedly deep at 64m below modern sea level 12km from the current coastline, while no marine deposits were encountered onshore. This implies that the position of the Eemian coastline presumably was similar to today's. The landscape reconstruction suggests Eemian coastal lagoons and thermokarst lakes, followed by Early to Middle Weichselian fluvially dominated terrestrial deposition. During the Late Weichselian, this fluvial landscape was transformed into a poorly drained accumulation plain, characterized by widespread and broad ice-wedge polygons. Finally, the shelf plain was flooded by the sea during the Holocene, resulting in the inundation and degradation of terrestrial permafrost and its transformation into subsea permafrost.

Published
2011

18. Paleontological records indicate the occurrence of open woodlands in a dry inland climate at the present-day Arctic coast in western Beringia during the Last Interglacial

Author

Kienast, Frank, Wetterich, Sebastian, Kuzmina, Svetlana, Schirrmeister, Lutz, Andreev, Andrei A., Tarasov, Pavel, Nazarova, Larisa, Kossler, Annette, Frolova, Larisa, Kunitsky, Viktor V., Kienast, Frank, Wetterich, Sebastian, Kuzmina, Svetlana, Schirrmeister, Lutz, Andreev, Andrei A., Tarasov, Pavel, Nazarova, Larisa, Kossler, Annette, Frolova, Larisa, and Kunitsky, Viktor V.

Abstract

Permafrost records, accessible at outcrops along the coast of Oyogos Yar at the Dmitry Laptev Strait, NE-Siberia, provide unique insights into the environmental history of Western Beringia during the Last Interglacial. The remains of terrestrial and freshwater organisms, including plants, coleopterans, chironomids, cladocerans, ostracods and molluscs, have been preserved in the frozen deposits of a shallow paleo-lake and indicate a boreal climate at the present-day arctic mainland coast during the Last Interglacial. Terrestrial beetle and plant remains suggest the former existence of open forest-tundra with larch (Larix dahurica), tree alder (Alnus incana), birch and alder shrubs (Duschekia fruticosa, Betula fruticosa, Betula divaricata, Betula nana), interspersed with patches of steppe and meadows. Consequently, the tree line was shifted to at least 270 km north of its current position. Aquatic organisms, such as chironomids, cladocerans, ostracods, molluscs and hydrophytes, indicate the formation of a shallow lake as the result of thermokarst processes. Steppe plants and beetles suggest low net precipitation. Littoral pioneer plants and chironomids indicate intense lake level fluctuations due to high evaporation. Many of the organisms are thermophilous, indicating a mean air temperature of the warmest month that was greater than 13 °C, which is above the minimum requirements for tree growth. These temperatures are in contrast to the modern values of less than 4 °C in the study area. The terrestrial and freshwater organism remains were found at a coastal exposure that was only 3.5 m above sea level and in a position where they should have been under sea during the Last Interglacial when the global sea level was 6–10 m higher than the current levels. The results suggest that during the last warm stage, the site was inland, and its modern coastal situation is the result of tectonic subsidence.

Published
2011
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19. Weichselian and Holocene palaeoenvironmental history of the Bol'shoy Lyakhovsky Island, New Siberian Archipelago, Arctic Siberia

Author

Andreev, Andrei A., Grosse, Guido, Schirrmeister, Lutz, Kuznetsova, Tatiana V., Kuzmina, Svetlana A., Bobrov, Anatoly A., Tarasov, Pavel E., Novenko, Elena Y., Meyer, Hanno, Derevyagin, Aleksandre Y., Kienast, Frank, Bryantseva, Anna, Kunitsky, Viktor V., Andreev, Andrei A., Grosse, Guido, Schirrmeister, Lutz, Kuznetsova, Tatiana V., Kuzmina, Svetlana A., Bobrov, Anatoly A., Tarasov, Pavel E., Novenko, Elena Y., Meyer, Hanno, Derevyagin, Aleksandre Y., Kienast, Frank, Bryantseva, Anna, and Kunitsky, Viktor V.

Abstract

Cryolithological, ground ice and fossil bioindicator (pollen, diatoms, plant macrofossils, rhizopods, insects, mammal bones) records from Bol'shoy Lyakhovsky Island permafrost sequences (73°20′N, 141°30′E) document the environmental history in the region for the past c. 115 kyr. Vegetation similar to modern subarctic tundra communities prevailed during the Eemian/Early Weichselian transition with a climate warmer than the present. Sparse tundra-like vegetation and harsher climate conditions were predominant during the Early Weichselian. The Middle Weichselian deposits contain peat and peaty soil horizons with bioindicators documenting climate amelioration. Although dwarf willows grew in more protected places, tundra and steppe vegetation prevailed. Climate conditions became colder and drier c. 30 kyr BP. No sediments dated between c. 28.5 and 12.05 14C kyr BP were found, which may reflect active erosion during that time. Herb and shrubby vegetation were predominant 11.6–11.3 14C kyr BP. Summer temperatures were c. 4 °C higher than today. Typical arctic environments prevailed around 10.5 14C kyr BP. Shrub alder and dwarf birch tundra were predominant between c. 9 and 7.6 kyr BP. Reconstructed summer temperatures were at least 4 °C higher than present. However, insect remains reflect that steppe-like habitats existed until c. 8 kyr BP. After 7.6 kyr BP, shrubs gradually disappeared and the vegetation cover became similar to that of modern tundra. Pollen and beetles indicate a severe arctic environment c. 3.7 kyr BP. However, Betula nana, absent on the island today, was still present. Together with our previous study on Bol'shoy Lyakhovsky Island covering the period between about 200 and 115 kyr, a comprehensive terrestrial palaeoenvironmental data set from this area in western Beringia is now available for the past two glacial–interglacial cycles.

Published
2009
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22. The use of CORONA images in remote sensing of periglacial geomorphology: an illustration from the NE Siberian coast

Author

Grosse, Guido, Schirrmeister, Lutz, Kunitsky, Viktor V., Hubberten, Hans-Wolfgang, Grosse, Guido, Schirrmeister, Lutz, Kunitsky, Viktor V., and Hubberten, Hans-Wolfgang

Abstract

CORONA images have been used for the mapping of periglacial features on the Bykovsky Peninsula and adjacent Khorogor Valley in northeast Siberia. Features, mapped and analysed within a geographical information system, include thermokarst depressions, thermo-erosional valleys, thermo-erosional cirques, thermokarst lakes, thermokarst lagoons and pingos. More than 50% of the area is strongly influenced by thermally-induced subsidence. Thermokarst in the area is probably less active today than in the early-middle Holocene.

Published
2005
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23. Late Saalian and Eemian palaeoenvironmental history of the Bol'shoy Lyakhovsky Island (Laptev Sea region, Arctic Siberia)

Author

ANDREEV, ANDREI A, GROSSE, GUIDO, SCHIRRMEISTER, LUTZ, KUZMINA, SVETLANA A, NOVENKO, ELENA YU, BOBROV, ANATOLY A, TARASOV, PAVEL E, ILYASHUK, BORIS P, KUZNETSOVA, TATIANA V, KRBETSCHEK, MATTHIAS, MEYER, HANNO, KUNITSKY, VIKTOR V, ANDREEV, ANDREI A, GROSSE, GUIDO, SCHIRRMEISTER, LUTZ, KUZMINA, SVETLANA A, NOVENKO, ELENA YU, BOBROV, ANATOLY A, TARASOV, PAVEL E, ILYASHUK, BORIS P, KUZNETSOVA, TATIANA V, KRBETSCHEK, MATTHIAS, MEYER, HANNO, and KUNITSKY, VIKTOR V

Abstract

Palaeoenvironmental records from permafrost sequences complemented by infrared stimulated luminescence (IRSL) and 230Th/U dates from Bol'shoy Lyakhovsky Island (73°20′N, 141°30′E) document the environmental history in the region for at least the past 200 ka. Pollen spectra and insect fauna indicate that relatively wet grasssedge tundra habitats dominated during an interstadial c. 200-170 ka BP. Summers were rather warm and wet, while stable isotopes reflect severe winter conditions. The pollen spectra reflect sparser grass-sedge vegetation during a Taz (Late Saalian) stage, c. 170-130 ka BP, with environmental conditions much more severe compared with the previous interstadial. Open Poaceae and Artemisia plant associations dominated vegetation at the beginning of the Kazantsevo (Eemian) c. 130 ka BP. Some shrubs (Alnus fruticosa, Salix, Betula nana) grew in more protected and wetter places as well. The climate was relatively warm during this time, resulting in the melting of Saalian ice wedges. Later, during the interglacial optimum, shrub tundra with Alnus fruticosa and Betula nana s.l. dominated vegetation. Climate was relatively wet and warm. Quantitative pollen-based climate reconstruction suggests that mean July temperatures were 4-5°C higher than the present during the optimum of the Eemian, while late Eemian records indicate significant climate deterioration. © 2004 Taylor & Francis.

Published
2004

24. Late Saalian and Eemian palaeoenvironmental history of the Bol'shoy Lyakhovsky Island (Laptev Sea region, Arctic Siberia)

Author

Andreev, Andrei A., Grosse, Guido, Schirrmeister, Lutz, Kuzmina, Svetlana A., Novenko, Elena Yu., Bobrov, Anatolya A, Tarasov, Pavel E., Kuznetsova, Tatyana V., Krbetschek, Matthias, Meyer, Hanno, Kunitsky, Viktor V., Andreev, Andrei A., Grosse, Guido, Schirrmeister, Lutz, Kuzmina, Svetlana A., Novenko, Elena Yu., Bobrov, Anatolya A, Tarasov, Pavel E., Kuznetsova, Tatyana V., Krbetschek, Matthias, Meyer, Hanno, and Kunitsky, Viktor V.

Abstract

Palaeoenvironmental records from permafrost sequences complemented by infrared stimulated luminescence (IRSL) and 230Th/U dates from Bol'shoy Lyakhovsky Island (7320'N, 14130'E) document the environmental history in the region for at least the past 200 ka. Pollen spectra and insect fauna indicate that relatively wet grass-sedge tundra habitats dominated during an interstadial c. 200–170 ka BP. Summers were rather warm and wet, while stable isotopes reflect severe winter conditions. The pollen spectra reflect sparser grass-sedge vegetation during a Taz (Late Saalian) stage, c. 170–130 ka BP, with environmental conditions much more severe compared with the previous interstadial. Open Poaceae and Artemisia plant associations dominated vegetation at the beginning of the Kazantsevo (Eemian) c. 130 ka BP. Some shrubs (Alnus fruticosa, Salix, Betula nana) grew in more protected and wetter places as well. The climate was relatively warm during this time, resulting in the melting of Saalian ice wedges. Later, during the interglacial optimum, shrub tundra with Alnus fruticosa and Betula nana s.l. dominated vegetation. Climate was relatively wet and warm. Quantitative pollen-based climate reconstruction suggests that mean July temperatures were 4–5 C higher than the present during the optimum of the Eemian, while late Eemian records indicate significant climate deterioration.

Published
2004
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25. Late Quaternary history of the accumulation plain North of the Chekanovsky Ridge (Lena Delta, Russia) : a multidisciplinary approach

Author

Schirrmeister, Lutz, Grosse, Guido, Schwamborn, Georg, Andreev, A. A., Meyer, Hanno, Kunitsky, Viktor V., Kuznetsova, Tatyana V., Dorozhkina, M. V., Pavlova, E. Y., Bobrov, A. A., Oezen, D., Schirrmeister, Lutz, Grosse, Guido, Schwamborn, Georg, Andreev, A. A., Meyer, Hanno, Kunitsky, Viktor V., Kuznetsova, Tatyana V., Dorozhkina, M. V., Pavlova, E. Y., Bobrov, A. A., and Oezen, D.

Abstract

Permafrost deposits were studied along the Olenyeksky and the Arinsky distributaries in the western Lena delta using a multidisciplinary approach that included sedimentological, mineralogical, stable-isotope, and paleoecological analyses in order to reconstruct the Late Quaternary landscape and environmental history of this Northeast.

Published
2003
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