Weichselian glaciation

Europe during the Weichselian and Würm cold periods

The last glacial period and its associated glaciation is known in Northern Europe as the Weichselian glaciation, Weichselian ice age (German: Weichsel-Eiszeit), Vistulian glaciation, Weichsel[1] or, less commonly, the Weichsel glaciation, Weichselian cold period (Weichsel-Kaltzeit), Weichselian glacial (Weichsel-Glazial), Weichselian Stage or, rarely, the Weichselian complex (Weichsel-Komplex). In the Alpine region it corresponds to the Würm glaciation. It was characterized by a large ice sheet that spread out from the Scandinavian Mountains[2] and extended as far as the east coast of Schleswig-Holstein, the March of Brandenburg and Northwest Russia.

In Northern Europe it was the youngest of the glacials of the Pleistocene ice age. The preceding warm period in this region was the Eemian interglacial. The last cold period began about 115,000 years ago and ended 11,700 years ago.[3] Its end corresponds with the end of the Pleistocene epoch and start of the Holocene.

Naming in other parts of the world

In other regions the glaciations of the last glacial period are given other names: for example that in the Alpine region is called the Würm glaciation, in the British Isles it is the Devensian glaciation and in North America, the Wisconsin glaciation.[4][5]

Development of the glaciation

The Fennosciandian Ice Sheet of the Weichselian glaciation most likely grew out of a mountain glaciation of small ice fields and ice caps in the Scandinavian Mountains. The initial glaciation of the Scandinavian Mountains would have been enabled by moisture coming from the Atlantic Ocean and the mountains high altitude. Perhaps the best modern analogues to this early glaciation are the ice fields of Andean Patagonia.[2] The Last Glacial Maximum extent was first reached 22 ka BP in the southern boundary of the ice sheet in Denmark, Germany and Western Poland. In Eastern Poland, Lithuania, Belorussia and Pskov Oblast in Russia the ice sheet reached its maximum extent about 19 ka BP. In the remaining of northwestern Russia the largest glacier advance occurred 17 ka BP.[6] As the ice margin started to recede 22-17 ka BP Denmark (except Bornholm), Germany, Poland and Belorussia were ice-free 16 ka BP. The ice margin then retreated until the Younger Dryas when the ice sheet stabilized. At this point most of Götaland, Gotland, all of the Baltic states and the southeastern coast of Finland had added to the ice-free regions. In Russia lake Ladoga and Onega and the bulk of Kola Peninsula and the White Sea were free from ice during the Younger Dryas. Before the Younger Dryas deglaciation had not been uniform and small ice sheet re-advances had occurred forming a series of end-moraine systems, notably those in Götaland.[6] When ice margin retreat resumed the ice sheet became increasingly concentrated in the Scandinavian Mountains (it had left Russia 10.6 ka PB and Finland 10.1 ka BP). Further retreat of the ice margin led the ice sheet to concentrate in two parts of the Scandinavian Mountains, one part in Southern Norway and another in Northern Sweden and Norway. These two centres were for a time linked. The linkage constituted a major drainage barrier that formed various large and ephemeral ice-dammed lakes. About 10.1 ka BP the linkage had disappeared and so did the Southern Norway centre of the ice sheet about thousand years later. The northern centre remained a few hundred years more so that by 9,7 ka BP the eastern Sarek Mountains hosted the last remnant of the Fennoscandian Ice Sheet.[6] As the ice sheet retreated to the Scandinavian Mountains this was not a return to its former mountain centered glaciation from which the ice sheet grew out, it was dissimilar in that the ice divide lagged behind as the ice mass concentrated in the west.[2]

Sequence and subdivisions of the Weichselian

Depiction of the Earth at the last glacial maximum. Illustration based on: Ice age terrestrial carbon changes revisited by Thomas J. Crowley (Global Biogeochemical Cycles, Vol. 9, 1995, pp. 377-389).

About 115,000 years ago[3] average temperatures dropped markedly and warmth-loving woodland species were displaced. This significant turning point in average temperatures marked the end of the Eemian interglacial and start of the Weichselian glacial stage. It is divided into three sections, based on the temperature variation: the Weichselian Early Glacial,[7][8] the Weichselian High Glacial[7] (also Weichselian Pleniglacial[8]) and the Weichselian Late Glacial.[8] During the Weichselian, there were frequent major variations in climate in the northern hemisphere, the so-called Dansgaard-Oeschger events.

The Weichsel Early Glacial (115,000 - 60,000 BC) is in turn divided into four stages:

In the Weichselian High Glacial (57,000 - c. 15,000 BC) the ice sheet advanced into North Germany. In this period, however, several interstadials have been documented.

The short "Weichselian Late Glacial" (12,500 - c. 10,000 BC) was the period of slow warming after the Weichselian High Glacial. It was however again interrupted by some colder episodes.

Following the last of these cold periods, the Younger Dryas, the Weichselian Glacial ended with an abrupt climb in temperature around 9,660 ± 40 BC.[9] This was the start of our present interglacial, the Holocene.

In addition to the above subdivisions the depositions of the Weichselian Late Glacial following the retreat of the ice sheet are divided into four stages: the Germanic Glacial (Germaniglazial) (Germany becomes ice-free), the Danish Glacial (Daniglazial) (Denmark becomes ice-free), The Gotland Glacial (Gotiglazial) (Gotland becomes ice-free) and the Finnish Glacial (Finiglazial) (Finland and Norway become ice-free).[10]

  • Maximum extent of the ice (Brandenburg Stage) during the Weichselian in North Germany (red line)
  • greatest extent of the older Saalian glaciation (yellow line)
    • . Note that the coastlines are modern, coastlines during the Weichselian were different as sea level was lower.

    See also

    References

    1. Whittow, John (1984). Dictionary of Physical Geography. London: Penguin, 1984, p. 580. ISBN 0-14-051094-X.
    2. 1 2 3 Fredin, Ola (2002). "Glacial inception and Quaternary mountain glaciations in Fennoscandia". Quaternary International. 95–96: 99 –112.
    3. 1 2 Litt et al. (2007: pp.45ff)
    4. F.J. Monkhouse Principles of Physical Geography, London: University of London Press, 1970 (7th edn.), p. 254. SBN 340 09022 7
    5. Whittow, John (1984). Dictionary of Physical Geography. London: Penguin, 1984, p. 265. ISBN 0-14-051094-X.
    6. 1 2 3 Stroeven, Arjen P.; Hättestrand, Clas; Kleman, Johan; Heyman, Jakob; Fabel, Derek; Fredin, Ola; Goodfellow, Bradley W.; Harbor, Jonathan M.; Jansen, John D.; Olsen, Lars; Caffee, Marc W.; Fink, David; Lundqvist, Jan; Rosqvist, Gunhild C.; Strömberg, Bo; Jansson, Krister N. (2016). "Deglaciation of Fennoscandia". Quaternary Science Reviews. 147: 91–121.
    7. 1 2 Wolfgang Schirmer, Quaternary field trips in central Europe, Volume 1, Pfeil, 1995, p. 375. ISBN 978-39-238-7191-9
    8. 1 2 3 John Dodson (ed.), Earth Systems and Society, New York, London, etc., Springer, 2010 p. 173. ISBN 978-90-481-8716-4
    9. Friedrich M, Kromer B, Spurk M, Hofmann J, Kaiser KF.(1999): Paleo-environment and radiocarbon calibration as derived from Late Glacial/Early Holocene tree-ring chronologies. In: Quaternary International 61:27–39.
    10. Karl N. Thome (1998), Einführung in das Quartär. Das Zeitalter der Gletscher (in German), Berlin: Springer-Verlag, pp. 72

    Literature

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