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The lake is oval in shape and surrounded by high banks. The lava was quarried for millstones from the Roman period until the introduction of iron rollers for grinding grain.[6]
The lake has no natural outlet but is drained by a tunnel dug before 1170 and rebuilt several times since. It is named for Fulbert, abbot of the monastery from 1152–1177, who is believed to have built it.[citation needed]
The eruption
Volcanism in Germany can be traced back for millions of years, related to the development of the European Cenozoic Rift System, which was caused by the collision between the African and Eurasianplates. Yet, the Eifel volcanism, which started in the East Eifel volcanic field around 450,000 BC, is the result of a hotspot.
The initial blasts of Laacher See, which took place in late spring or early summer at around 11,000 BC, flattened trees up to four kilometres away. The magma opened a route to the surface that erupted for about ten hours, with the plume probably reaching a height of 35 kilometres. Activity continued for several weeks or months, producing pyroclastic currents that covered valleys up to ten kilometres away with sticky tephra. Near the crater, deposits reach over fifty metres in thickness, and even five kilometres away they are still ten metres thick. All plants and animals for a distance of about sixty kilometres to the northeast and forty kilometres to the southeast must have been wiped out.[7]
An estimated 6 km3 (1.4 cu mi) of magma erupted,[8] producing around 16 km3 (3.8 cu mi) of tephra.[9] This 'huge' Plinian eruption thus had a Volcanic Explosivity Index (VEI) of 6.
Tephra deposits from the eruption dammed the Rhine, creating a 140 km2 (50 sq mi) lake. When the dam broke, an outburst flood swept downstream, leaving deposits as far away as Bonn.[8] The fallout has been identified in an area of more than 300,000 square kilometres, stretching from central France to northern Italy and from southern Sweden to Poland, making it an invaluable tool for chronological correlation of archaeological and palaeoenvironmental layers across the area.[10]
The wider effects of the eruption were limited, amounting to several years of cold summers and up to two decades of environmental disruption in Germany. However, the lives of the local population, known as the Federmesser culture, were disrupted. Before the eruption, they were a sparsely distributed people who subsisted by foraging and hunting, using both spears and bows and arrows. According to archaeologist Felix Riede, after the eruption the area most affected by the fallout, the Thuringian Basin occupied by the Federmesser, appears to have been largely depopulated, whereas populations in southwest Germany and France increased. Two new cultures, the Bromme of southern Scandinavia and the Perstunian of northeast Europe emerged. These cultures had a lower level of toolmaking skills than the Federmesser, particularly the Bromme who appear to have lost the bow and arrow technology. In Riede's view the decline was a result of the disruption caused by the Laacher See volcano.[11]
The eruption was discussed as a possible cause for the Younger Dryas, a period of global cooling near the end of the last glacial maximum that appeared to coincide with the time of the Laacher See eruption.[12][13] A new radiocarbon date for the eruption, published in 2021, suggested that the Younger Dryas began about 130 years after the eruption,[14] though this new date was challenged as having perhaps been affected by radiocarbon dead magmatic carbon, which was not accounted for and would have made the date appear too old.[15] The current best estimates for the age of the Laacher See eruption are 12,880 ± 40 years BP[16] or 13,006 ± 9 calibrated years before present,[14] depending on whether the radiocarbon date was affected by magmatic carbon dioxide. If the date was affected by magmatic carbon dioxide, the Laacher See eruption would then have occurred immediately before the onset of the Younger Dryas Event, and could have acted as a trigger. If the radiocarbon-derived date of 13,006 calibrated years before present is correct, the Laacher See eruption may have still affected climate as part of a large cluster of volcanic events happening in the 130 years immediately before the event,[17] though it would not have immediately preceded the event.
^de Klerk, Pim; et al. (2008). "Environmental impact of the Laacher See eruption at a large distance from the volcano: Integrated palaeoecological studies from Vorpommern (NE Germany)". Palaeogeography, Palaeoclimatology, Palaeoecology. 270 (1–2): 196–214. Bibcode:2008PPP...270..196D. doi:10.1016/j.palaeo.2008.09.013.
^Bogaard, Paul van den (1995). "40Ar/39Ar ages of sanidine phenocrysts from Laacher See Tephra (12,900 yr BP): Chronostratigraphic and petrological significance". Earth and Planetary Science Letters. 133 (1–2): 163–174. Bibcode:1995E&PSL.133..163V. doi:10.1016/0012-821X(95)00066-L.
^Reinig, Frederick; Wacker, Lukas; Jöris, Olaf; Oppenheimer, Clive; Guidobaldi, Giulia; Nievergelt, Daniel; et al. (30 June 2021). "Precise date for the Laacher See eruption synchronizes the Younger Dryas". Nature. 595 (7865): 66–69. Bibcode:2021Natur.595...66R. doi:10.1038/S41586-021-03608-X. ISSN1476-4687. WikidataQ107389873. [Measurements] firmly date the [Laacher See eruption] to 13,006 ± 9 calibrated years before present (BP; taken as AD 1950), which is more than a century earlier than previously accepted.
Park, Cornelia; Schmincke, Hans-Ulrich (1997). "Lake Formation and Catastrophic Dam Burst during the Late Pleistocene Laacher See Eruption (Germany)". Naturwissenschaften. 84 (12): 521–525. Bibcode:1997NW.....84..521P. doi:10.1007/s001140050438. S2CID36411187.
Riede, Felix (2008). "The Laacher See-eruption (12,920 BP) and material culture change at the end of the Allerød in Northern Europe". Journal of Archaeological Science. 35 (3): 591–599. Bibcode:2008JArSc..35..591R. doi:10.1016/j.jas.2007.05.007.