A 40 ka record of temperature and permafrost conditions in northwestern Europe from noble gases in the Ledo‐Paniselian Aquifer (Belgium) |
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| Authors: | Petra Corinne Blaser Rolf Kipfer Heinz Hugo Loosli Kristine Walraevens Marc van Camp Werner Aeschbach‐Hertig |
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| Institution: | 1. petraconsult, Uetikon am See, Switzerland;2. Department of Water Resources and Drinking Water, Eawag, Swiss Federal Institute of Aquatic Science and Technology, Duebendorf, Switzerland;3. and Institute of Isotope Geochemistry and Mineral Resources, ETH Zurich, Zurich, Switzerland;4. Department of Climate and Environmental Physics, University of Bern, Bern, Switzerland;5. Laboratory for Applied Geology and Hydrogeology, Ghent University, Ghent, Belgium;6. Institut für Umweltphysik, Heidelberg University, Heidelberg, Germany |
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| Abstract: | The Ledo‐Paniselian Aquifer in Belgium offers unique opportunities to study periglacial groundwater recharge during the Last Glacial Maximum (LGM), as it was located close to the southern boundary of the ice sheets at that time. Groundwater residence times determined by 14C and 4He reveal a sequence of Holocene and Pleistocene groundwaters and a gap between about 14 and 21 ka, indicating permafrost conditions which inhibited groundwater recharge. In this paper, a dataset of noble gas measurements is used to study the climatic evolution of the region. The derived recharge temperatures indicate that soil temperatures in the periods just before and after the recharge gap were only slightly above freezing, supporting the hypothesis that permafrost caused the recharge gap. The inferred glacial cooling of 9.5°C is the largest found so far by the noble gas method. Yet, compared to other palaeoclimate reconstructions for the region, recharge temperatures deduced from noble gases for the cold periods tend to be rather high. Most likely, this is due to soil temperatures being several degrees higher than air temperatures during periods with extended snow cover. Thus the noble‐gas‐derived glacial cooling of 9.5°C is only a lower limit of the maximum cooling during the LGM. Some samples younger than the recharge gap are affected by degassing, possibly related to gas production during recharge in part of the recharge area, especially during times of melting permafrost. The findings of this study, such as the occurrence of a recharge gap and degassing related to permafrost and its melting, are significant for groundwater dynamics and geochemistry in periglacial areas. Copyright © 2010 John Wiley & Sons, Ltd. |
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| Keywords: | noble gas temperatures groundwater Pleistocene Holocene permafrost palaeoclimate recharge gap degassing excess air Ledo‐Paniselian Aquifer |
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