Your search keyword '"Carl Regnéll"' showing total 16 results

1. High‐resolution chronology of 24 000‐year long cores from two lakes in the Polar Urals, Russia, correlated with palaeomagnetic inclination records with a distinct event about 20 000 years ago

Author

Reidun F. Eldegard, Haflidi Haflidason, Jo Brendryen, John Inge Svendsen, Sædis Olafsdottir, Jan Mangerud, and Carl Regnéll

Subjects

Paleontology, Arts and Humanities (miscellaneous), Event (relativity), Earth and Planetary Sciences (miscellaneous), Polar, High resolution, Geology, Chronology

Abstract

Based on radiocarbon dating, a tephra horizon, varve counts and palaeomagnetism, detailed age models covering the last ~24 k cal a bp, have been developed for the stratigraphy in the lakes Bolshoye Shchuchye and Maloye Shchuchye in the Polar Ural Mountains, Russia. The inclination curves from these lakes show nearly identical palaeomagnetic secular variations in the studied cores from both lakes, allowing for a precise correlation between the cores. A large and very distinct inclination deviation, named the Bolshoye Shchuchye Event, was identified in all cores retrieved from both lakes. It lasted over a period of 1245 years, from 20 470 to 19 225 cal a bp. The well-dated palaeomagnetic inclination graph offers a new possibility to correlate archives in this part of the Arctic for the last ~24 k cal a bp, probably also over longer distances. The sedimentation rate shows the same trend in all cores from both lakes, including high input during the Last Glacial Maximum and gradually lowering after ~18 k cal a bp to lower and stable Holocene values. publishedVersion

Published

2021

2. Deglaciation of the Scandinavian Ice Sheet and a Younger Dryas ice cap in the outer Hardangerfjorden area, southwestern Norway

Author

Haflidi Haflidason, Carl Regnéll, John Inge Svendsen, Jan Mangerud, and Jason P. Briner

Subjects

Archeology, geography, Paleontology, geography.geographical_feature_category, Deglaciation, Geology, Ice caps, Younger Dryas, Ice sheet, Ecology, Evolution, Behavior and Systematics

Abstract

Understanding past responses of ice sheets to climate change provides an important long-term context for observations of present day, and projected future, ice-sheet change. In this work, we reconstruct the deglaciation of the marine-terminating western margin of the Scandinavian Ice Sheet in the outer Hardangerfjorden area of southwestern Norway, following the Last Glacial Maximum (LGM) until the start of the Holocene. We base our interpretations on a combination of geomorphological mapping using high-resolution (LiDAR) terrain models, 68 new cosmogenic nuclide 10Be exposure ages and radiocarbon-dated lake sediment cores, supported by the stratigraphic position of the 12.1 ka Vedde Ash. We show that even the highest mountain summits in the area (˜1200–1400 m a.s.l.) were ice-covered during the LGM, thus settling debates concerning the Scandinavian Ice Sheet thickness in this region. These summits emerged as nunataqs through the ice sheet about 22–18 ka, potentially owing to upstream ice thinning caused by the break-up and retreat of the Norwegian Channel Ice Stream. Following the break-up of the Norwegian Channel Ice Stream, the ice margin seemingly stabilized at the outermost coast for 3500–5500 years before the mouth of Hardangerfjorden became ice free at c. 14.5 ka. Subsequently, during the Bølling and Allerød periods, the ice sheet retreated rapidly into the inner parts of Hardangerfjorden before a major ice sheet re-advance during the Younger Dryas. We identify and reconstruct a sizeable, independent ice cap on the Ulvanosa mountain massif during the Younger Dryas (YD), a massif that earlier was mapped as covered by the Scandinavian Ice Sheet during the YD. We also document ice-free areas that are more extensive than previously thought between Hardangerfjorden and Matersfjorden during the YD. publishedVersion

Published

2021

3. Western Siberia experienced rapid shifts in moisture source and summer water balance during the last deglaciation and early Holocene

Author

Carl Regnéll, Owen Cowling, Haflidi Haflidason, John Inge Svendsen, Jan Mangerud, Elizabeth K. Thomas, and Jo Brendryen

Subjects

Water balance, Arts and Humanities (miscellaneous), Moisture, Earth and Planetary Sciences (miscellaneous), Deglaciation, Paleontology, Physical geography, Water cycle, Western siberia, Holocene, Geology

Published

2021

4. List of contributors

Author

Naki Akçar, Lis Allaart, James L. Allard, Nuria Andrés, Florina Ardelean, Mircea Ardelean, Lovísa Ásbjörnsdóttir, Rachael S. Avery, Ívar Örn Benediktsson, Oana Berzescu, Albertas Bitinas, Andreas Börner, Skafti Brynjólfsson, Mirosław Błaszkiewicz, Marc Calvet, Chris D. Clark, Magali Delmas, Mariana Esteves, Marcelo Fernandes, José M. Fernández-Fernández, José M. García-Ruiz, Philip L. Gibbard, Carlo Giraudi, Neil F. Glasser, Sarah L. Greenwood, Yanni Gunnell, Rimante Guobyte, Berit Oline Hjelstuen, Anna L.C. Hughes, Philip D. Hughes, Susan Ivy-Ochs, Mark D. Johnson, Olga Korsakova, Piotr Kłapyta, Amaelle Landais, Juha Pekka Lunkka, Michał Makos, Jan Mangerud, Leszek Marks, Giovanni Monegato, Filipa Naughton, Dmitry Nazarov, Olga Nosova, Marc Oliva, Alexandru Onaca, David Palacios, Henry Patton, Richard J.J. Pope, Carl Regnéll, Jürgen M. Reitner, Théo Reixach, Adriano Ribolini, Vincent Rinterknecht, Natalia Vazquez Riveiros, Teresa Rodrigues, María F. Sánchez-Goñi, Hans Petter Sejrup, Matteo Spagnolo, John Inge Svendsen, Matt D. Tomkins, Samuel Toucanne, Anna Tołoczko-Pasek, Karol Tylmann, Petru Urdea, Andrey Vashkov, Monica C.M. Winsborrow, Jamie C. Woodward, and Jerzy Zasadni

Published

2023

5. The Polar Ural Mountains: deglaciation history

Author

John Inge Svendsen, Jan Mangerud, Dmitry Nazarov, and Carl Regnéll

Published

2023

6. Meteorite crater re-interpreted as iceberg pit in west-central Sweden

Author

Gustaf Peterson Becher, Christian Öhrling, Carl Regnéll, and Henrik Mikko

Subjects

Meteorite, Impact crater, Geochemistry, Deglaciation, Paleontology, Geology, Iceberg

Abstract

This study shows the occurrence of numerous iceberg imprints on the bottom of former ice-dammed lakes in Harjedalen, west-central Sweden. Discussion of the genesis of the so-called “impact crater” ...

Published

2020

7. The Ural Mountains: glacial landforms prior to the Last Glacial Maximum

Author

Dmitry Nazarov, Jan Mangerud, Carl Regnéll, and John Inge Svendsen

Subjects

Glacial landform, Last Glacial Maximum, Physical geography, Geology

Published

2022

8. Glacial landscapes of the Ural Mountains

Author

Carl Regnéll, John Inge Svendsen, Jan Mangerud, and Dmitry Nazarov

Subjects

Physical geography, Glacial period, Geology

Published

2022

9. The Ural Mountains: glacial landforms from the Last Glacial Maximum

Author

Dmitry Nazarov, Carl Regnéll, Jan Mangerud, and John Inge Svendsen

Subjects

Glacial landform, Last Glacial Maximum, Physical geography, Geology

Published

2022

10. Ice-dammed lakes of Scandinavia - a key to the pattern and chronology of the final decay of the Scandinavian Ice Sheet

Author

Sarah L. Greenwood, Robin Blomdin, Christian Öhrling, Bradley W. Goodfellow, Richard Gyllencreutz, Joachim Regnéll, John Inge Svendsen, Carl Regnéll, Jan Mangerud, Henrik Mikko, and Gustaf Peterson Becher

Subjects

geography, geography.geographical_feature_category, Key (lock), Physical geography, Ice sheet, Geology, Chronology

Abstract

Here we present the use of ice-dammed lake-related landforms and sediments for reconstructing the final phases of decay of the Scandinavian Ice Sheet.In the late stages of the deglaciation, extensive glacial lakes were dammed between the easterly retreating Scandinavian Ice Sheet and the water divide within the mountains to the west. Using high-resolution airborne LiDAR-data, shorelines and other landforms relating to these ice-dammed lakes have now been discovered over larger areas and in greater numbers than previously known, opening a treasure trove of palaeoglaciological information of vast potential for reconstructing the final decay phase of the Scandinavian Ice Sheet.The geomorphological imprint of the ice-dammed lakes is of particular importance in northern Scandinavia, as geological evidence pertaining unequivocally to the final ice sheet decay is sparse. Its interpretation is complicated since the ice sheet is thought to have mainly been cold-based during final decay, inhibiting sliding at the ice-bed interface and limiting the construction (or destruction) of landforms indicative of the changing shape and flow of the ice sheet. Furthermore, dated sediment sequences marking the onset of ice-free conditions are woefully few in northern Scandinavia. Likewise, available cosmogenic nuclide exposure dates provide high age uncertainty and inadequate geographical cover, leaving the timing and location of final ice sheet decay still elusive.Using examples from northern and central Scandinavia, we show that ice-dammed lakes are an intricate part of the deglacial dynamics and show how mapping and dating them offer a solution to these problems. Even with a frozen ice-bed interface, surface melting and meltwater drainage creates landforms unequivocally associated with ice sheet decay: drainage channels, dammed lake shorelines, and deltas. Meltwater drainage routes and ice-dammed lakes are therefore powerful tools for reconstructing a disintegrating ice sheet; a ponded lake reveals the location of its requisite ice-dam, and drainage pathways reveal ice-free conditions. A dated sequence of ice-dammed lake sediments can therefore constrain both ice and lake coverage at that time for a much larger area than the dated site itself. Furthermore, the extent of different ice-dammed lake stages and their requisite ice-damming positions enables the pattern of ice margin change to be traced, and the relative age of ice-marginal positions determined using cross-cutting relations. The shorelines’ present-day tilts are also used to inform patterns and magnitudes of postglacial isostatic uplift, information otherwise lacking from the continental interior but of particular importance for modelling former ice sheet volumes and understanding the crustal response to ice sheet loading. Reconstructing the extents and timing of ice-dammed lakes and the study of related landforms and deposits can therefore greatly improve our understanding of the final decay of the Scandinavian Ice Sheet and provide potential analogues for the predicted future behaviours of modern ice sheets.

Published

2021

11. Rapid climate changes during the Lateglacial and the early Holocene as seen from plant community dynamics in the Polar Urals, Russia

Author

Charlotte Clarke, Aage Paus, Haflidi Haflidason, Maren S. Johansen, Jo Brendryen, Anne E. Bjune, Inger Greve Alsos, Jan Mangerud, Mary E. Edwards, John Inge Svendsen, and Carl Regnéll

Subjects

Paleontology, Climate change, Plant community, medicine.disease_cause, Arts and Humanities (miscellaneous), Pollen, Earth and Planetary Sciences (miscellaneous), medicine, VDP::Mathematics and natural science: 400::Zoology and botany: 480, Polar, Physical geography, Holocene, Geology, VDP::Matematikk og Naturvitenskap: 400::Zoologiske og botaniske fag: 480

Abstract

A detailed, well-dated record of pollen and sedimentary ancient DNA (sedaDNA) for the period 15 000–9500 cal a bp describes changes at Lake Bolshoye Shchuchye in the Polar Ural Mountains, located far east of the classical Lateglacial sites in western Europe. Arctic tundra rapidly changed to lusher vegetation, possibly including both dwarf (Betula nana) and tree birch (B. pubescens), dated in our record to take place 14 565 cal a bp, coincident with the onset of the Bølling in western Europe; this was paralleled by increased summer temperatures. A striking feature is an early decline in Betula pollen and sedaDNA reads 300 years before the onset of the Younger Dryas (YD) in western Europe. Given the solid site chronology, this could indicate that the YD cooling started in Siberia and propagated westwards, or that the vegetation reacted to the inter-Allerød cooling at 13 100 cal a bp and did not recover during the late Allerød. During the YD, increases in steppe taxa such as Artemisia and Chenopodiaceae suggest drier conditions. At the onset of the Holocene, the vegetation around the lake reacted fast to the warmer conditions, as seen in the increase of arboreal taxa, especially Betula, and a decrease in herbs such as Artemisia and Cyperaceae. publishedVersion

Published

2021

12. A 24,000-year ancient DNA and pollen record from the Polar Urals reveals temporal dynamics of arctic and boreal plant communities

Author

Ludovic Gielly, Aage Paus, Charlotte Clarke, John Inge Svendsen, Anne E. Bjune, Carl Regnéll, Paul D.M. Hughes, Inger Greve Alsos, Mary E. Edwards, Jan Mangerud, and Haflidi Haflidason

Subjects

010506 paleontology, Archeology, Global and Planetary Change, Carex, VDP::Matematikk og Naturvitenskap: 400::Basale biofag: 470::Molekylærbiologi: 473, 010504 meteorology & atmospheric sciences, biology, Ecology, VDP::Mathematics and natural science: 400::Basic biosciences: 470::Molecular biology: 473, Geology, Plant community, biology.organism_classification, medicine.disease_cause, 01 natural sciences, VDP::Humanities: 000, Tundra, VDP::Humaniora: 000, Boreal, Pollen, medicine, Dominance (ecology), Bryophyte, Younger Dryas, Ecology, Evolution, Behavior and Systematics, 0105 earth and related environmental sciences

Abstract

A 24,000-year record of plant community dynamics, based on pollen and ancient DNA from the sediments (sedaDNA) of Lake Bolshoye Shchuchye in the Polar Ural Mountains, provides detailed information on the flora of the Last Glacial Maximum (LGM) and also changes in plant community composition and dominance. It greatly improves on incomplete records from short and fragmented stratigraphic sequences found in exposed sedimentary sections in the western Russian Arctic. In total, 162 plant taxa were detected by sedaDNA and 115 by pollen analysis. Several shifts in dominance between and within plant functional groups occurred over the studied period, but most taxa appear to have survived in situ. A diverse arctic-alpine herb flora characterised the interval ca. 24,000–17,000 cal years BP and persisted into the Holocene. Around 17,000 cal years BP, sedges (e.g. Carex) and bryophytes (e.g. Bryum, Aulacomnium) increased. The establishment of shrub-tundra communities of Dryas and Vaccinium sp., with potentially some Betula pubescens trees (influx ∼290 grains cm2 year−1), followed at ca. 15,000 cal years BP. Forest taxa such as Picea and ferns (e.g. Dryopteris fragrans, Gymnocarpium dryopteris) established near the lake from ca. 10,000 cal years BP, followed by the establishment of Larix trees from ca. 9000 cal years BP. Picea began to decline from ca. 7000 cal years BP. A complete withdrawal of forest tree taxa occurred by ca. 4000 cal years BP, presumably due to decreasing growing-season temperatures, allowing the expansion of dwarf-shrub tundra and a diverse herb community similar to the present-day vegetation mosaic. Contrary to some earlier comparative studies, sedaDNA and pollen from Lake Bolshoye Shchuchye showed high similarity in the timing of compositional changes and the occurrence of key plant taxa. The sedaDNA record revealed several features that the pollen stratigraphy and earlier palaeorecords in the region failed to detect; a sustained, long-term increase in floristic richness since the LGM until the early Holocene, turnover in grass and forb genera over the Pleistocene-Holocene transition, persistence of a diverse arctic-alpine flora over the late Quaternary, and a variable bryophyte flora through time. As pollen records are often limited by taxonomic resolution, differential productivity and dispersal, sedaDNA can provide improved estimates of floristic richness and is better able to distinguish between different plant assemblages. However, pollen remains superior at providing quantitative estimates of plant abundance changes and detecting several diverse groups (e.g. Poaceae, Cyperaceae, Asteraceae) which may be underreported in the sedaDNA. Joint use of the two proxies provided unprecedented floristic detail of past plant communities and helped to distinguish between long-distance transport of pollen and local presence, particularly for woody plant taxa.

Published

2020

13. Glacial and climate history of the last 24 000 years in the Polar Ural Mountains, Arctic Russia, inferred from partly varved lake sediments

Author

John Inge Svendsen, Haflidi Haflidason, Jan Mangerud, and Carl Regnéll

Subjects

010506 paleontology, Archeology, Varve, 010504 meteorology & atmospheric sciences, Geology, Climate history, 01 natural sciences, Arctic, Polar, Glacial period, Physical geography, Ecology, Evolution, Behavior and Systematics, 0105 earth and related environmental sciences

Published

2018

14. Glacial and environmental changes over the last 60 000 years in the Polar Ural Mountains, Arctic Russia, inferred from a high‐resolution lake record and other observations from adjacent areas

Author

John Inge Svendsen, Haflidi Haflidason, Lars Martin B. Færseth, Øystein S. Lohne, Joerg M. Schaefer, Richard Gyllencreutz, Dmitry Nazarov, Morten N. Hovland, Mona Henriksen, Carl Regnéll, and Jan Mangerud

Subjects

010506 paleontology, Archeology, 010504 meteorology & atmospheric sciences, Geomorphological mapping, Resolution (electron density), Geology, 01 natural sciences, Arctic, Polar, Glacial period, Physical geography, Ecology, Evolution, Behavior and Systematics, 0105 earth and related environmental sciences

Abstract

Our knowledge about the glaciation history in the Russian Arctic has to a large extent been based on geomorphological mapping supplemented by studies of short stratigraphical sequences found in exp ...

Published

2018

15. Extending the known distribution of the Vedde Ash into Siberia: occurrence in lake sediments from the Timan Ridge and the Ural Mountains, northern Russia

Author

Carl Regnéll, Haflidi Haflidason, John Inge Svendsen, Sean Pyne-O'Donnell, Asian School of the Environment, and Earth Observatory of Singapore

Subjects

010506 paleontology, Archeology, geography, geography.geographical_feature_category, 010504 meteorology & atmospheric sciences, Geochemistry, Geology, Glacial-interglacial Transition, 01 natural sciences, Tephra Horizons, Geography::Physical geography [Social sciences], Ridge, Ecology, Evolution, Behavior and Systematics, 0105 earth and related environmental sciences

Abstract

Tephra shards from the Vedde Ash eruption have been identified in two lakes from northwestern Russia and the Polar Ural Mountains. This is the most distal and easternmost occurrence of this regional tephra marker horizon found so far and it extends the area of the Vedde Ash tephra more than 1700 km further east than previously documented. This means that particles the size of fine sand have travelled more than 4000 km from the Katla volcano source, south Iceland. These findings offer a new possibility to correlate archives over a very long distance in the time period around the Younger Dryas. This work was financially supported by TheResearch Council of Norway and is a contribution to the project‘Climate History along the Arctic Seaboard of Eurasia’ (CHASE)(NRC 255415). The coring fieldwork was carried out in 2000 at LakeYamozero and 2009 at Lake Bolshoye Shchuchye during the formerresearch projects ‘Paleo Environment and Climate History of theRussian Arctic’ (PECHORA II) and ‘The Ice Age Development andHuman Settlement in Northern Eurasia’ (ICEHUS) funded by theResearch Council of Norway (NRC 167131 and NRC 176176048). M.Henriksen (Universityof Bergen)supplied the core material selected forthe Lake Yamozero cryptotephra detection work. The Lake Yamozerogeochemical analysis was conducted with funding from the NERCRAPID Climate Change thematic programme, project NE/C509158/1‘Precise chronology of the timing of changes in behaviour of the NorthAtlantic THC and their forcing effects, 16–8kaBP’.

Published

2018

16. Tracing the last remnants of the Scandinavian Ice Sheet: Ice-dammed lakes and a catastrophic outburst flood in northern Sweden

Author

Carl Regnéll, Jan Mangerud, and John Inge Svendsen

Subjects

Fennoscandian ice sheet, 010506 paleontology, Archeology, Isostasy, 010504 meteorology & atmospheric sciences, Glacial lake outburst flood, Outburst flood, IDL, 01 natural sciences, Quaternary, Glaciation, Early Holocene, Tectonic uplift, Deglaciation, Glacial, Glacial period, Ecology, Evolution, Behavior and Systematics, Holocene, 0105 earth and related environmental sciences, Global and Planetary Change, geography, geography.geographical_feature_category, Geomorphology, Geology, GLOF, Scandinavia, Physical geography, Ice sheet

Abstract

We present geomorphological evidence of large, previously undocumented, early Holocene ice-dammed lakes in the Scandinavian Mountains of northwestern Sweden. The lakes extents indicate that the last remnants of the Scandinavian Ice Sheet were located east of the mountain range. Some early pioneering works have presented similar reconstructions, whereas more recently published reconstructions place the last ice remnants in the high mountains of Sarek. Using high-resolution airborne LiDAR data we have mapped a large number of hitherto undocumented shorelines in some of the main valleys within the northern Scandinavian mountain range. Our results indicate that a larger system of ice-dammed lakes existed in this region than previously thought. The lakes were dammed between the main water divide to the west and the retreating ice sheet margin to the east. The shorelines dip towards the northwest with gradients ranging from 0.5 to 0.4 m/km, from the oldest to the youngest. Further, we have compiled Lateglacial and Holocene shoreline data along the Norwegian coast and from within the Baltic Sea basin and reconstructed the isostatic uplift along a 1400 km long northwest-southeast transect from the Norwegian Sea to Lake Ladoga. By comparing the measured ice-dammed lake shoreline gradients to the dated marine shorelines, we infer that the lakes may have existed for several centuries following 10.2 cal ka BP. We also describe large deposits and extensive erosive features, which demonstrate that a catastrophic glacial lake outburst flood (GLOF) took place eastward along the Pite River Valley. Based on cross-cutting relations to raised shorelines developed in the early Holocene Ancylus Lake (Baltic Sea basin) we conclude that the flood and thus the final phase of deglaciation took place within the time interval 10.3–9.9 cal ka BP. publishedVersion

Published

2019