Deglaciation of the highest mountains in Scandinavia at the Younger Dryas–Holocene transition: evidence from surface exposure‐age dating of ice‐marginal moraines-Reference-Cited by-同舟云学术

Deglaciation of the highest mountains in Scandinavia at the Younger Dryas–Holocene transition: evidence from surface exposure‐age dating of ice‐marginal moraines

Published:2023-12-27 Issue: Volume: Page:
ISSN:0300-9483
Container-title:Boreas
language:en
Short-container-title:Boreas

Author:

Matthews John A.¹^ORCID,Linge Henriette²^ORCID,Nesje Atle²,Wilson Peter³,Mourne Richard W.⁴,Winkler Stefan⁵,Owen Geraint¹,Hill Jennifer L.⁶,Haselberger Stefan⁷,Olsen Jesper⁸

Affiliation:

1. Department of Geography Swansea University Singleton Park Swansea SA2 8PP Wales, UK

2. Department of Earth Science University of Bergen and Bjerknes Centre for Climate Research NO‐5020 Bergen Norway

3. School of Geography and Environmental Sciences Ulster University Coleraine Co. Londonderry BT52 1SA Northern Ireland, UK

4. School of Architecture and Environment University of the West of England Coldharbour Lane Bristol BS16 1QY England, UK

5. Department of Geography and Geology Julius‐Maximillians‐University Würzburg Am Hubland D‐9707 Würzburg Germany

6. Academic Development Unit University of Gloucestershire Cheltenham GL50 2RH UK

7. Department of Geography and Regional Research University of Vienna Universitätstraβe 7 1010 Vienna Austria

8. Aarhus AMS Centre, Department of Physics and Astronomy Aarhus University 8000 Aarhus C Denmark

Abstract

Surface exposure–age dating was applied to rock surfaces associated with ice‐marginal moraines at elevations of ~1520–1780 m a.s.l. on the slopes of Galdhøpiggen and Glittertinden, the two highest mountains in Scandinavia located in the Jotunheimen mountains of central southern Norway. This is important for understanding the pattern and timing of wastage of the Scandinavian Ice Sheet at the Younger Dryas–Holocene transition. Cosmogenic exposure dating (here 10Be dating) of boulders from the moraine ridges yielded overall mean ages (corrected for glacio‐isostatic uplift, surface erosion and snow shielding) of ~11.6 ka from Galdhøpiggen and ~11.2 ka from Glittertinden. Similar 10Be ages were also obtained from additionally collected proximal and distal erratic boulders and bedrock samples. These enabled age calibration of Schmidt‐hammer R‐values and independent Schmidt‐hammer exposure‐age dating (SHD) of the moraine ridges, which yielded comparable mean SHD ages of ~10.8 and ~10.6 ka from the Galdhøpiggen and Glittertinden sites, respectively. Taking account of the age resolution and other limitations of both dating techniques, the results suggest that the two sets of moraines have approximately the same age but that neither technique can distinguish unambiguously between moraine formation in the late Younger Dryas or Early Holocene. Together with features of moraine‐ridge morphology and estimates of equilibrium‐line altitude depression of ~360–575 m (corrected for land uplift), the results imply moraine formation during short‐lived re‐advances of active glaciers, at least the lower reaches of which were warm‐based. It is concluded that the local glaciers remained active and advanced during deglaciation either very late in the Younger Dryas or very early in the Holocene, possibly in response to the Preboreal Oscillation at ~11.4 ka. The study supports the concept of a thin Younger Dryas ice sheet and places time constraints on the timing of final deglaciation in southern Norway.

Publisher

Wiley

Subject

Geology,Archeology,Ecology, Evolution, Behavior and Systematics

Link

https://onlinelibrary.wiley.com/doi/pdf/10.1111/bor.12644

Reference132 articles.

1. Pleistocene Evolution of a Scandinavian Plateau Landscape

2. Rates of postglacial rock weathering on glacially scoured outcrops (abisko–riksgränsen area, 68°n)

3. Andreassen L. M.(ed.)2022:Breer og fonner i Norge.Norges Vassdrags‐ og Energidirektorat (NVE) Rapport 3/2022 1–50.

4. Andreassen L. M.&Winsvold S. H.(eds.)2012:Inventory of Norwegian Glaciers.Norwegian Water Resources and Energy Directorate (NVE) Rapport 38‐2012 242 pp.