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Raimund Muscheler

Raimund Muscheler

Professor

Raimund Muscheler

Persistent link between solar activity and Greenland climate during the Last Glacial Maximum

Author

  • Florian Adolphi
  • Raimund Muscheler
  • Anders Svensson
  • Ala Aldahan
  • Goran Possnert
  • Jurg Beer
  • Jesper Sjolte
  • Svante Björck
  • Katja Matthes
  • Remi Thieblemont

Summary, in English

Changes in solar activity have previously been proposed to cause decadal- to millennial-scale fluctuations in both the modern and Holocene climates(1). Direct observational records of solar activity, such as sunspot numbers, exist for only the past few hundred years, so solar variability for earlier periods is typically reconstructed from measurements of cosmogenic radionuclides such as Be-10 and C-14 from ice cores and tree rings(2,3). Here we present a high-resolution Be-10 record from the ice core collected from central Greenland by the Greenland Ice Core Project (GRIP). The record spans from 22,500 to 10,000 years ago, and is based on new and compiled data(4-6). Using C-14 records(7,8) to control for climate-related influences on Be-10 deposition, we reconstruct centennial changes in solar activity. We find that during the Last Glacial Maximum, solar minima correlate with more negative delta O-18 values of ice and are accompanied by increased snow accumulation and sea-salt input over central Greenland. We suggest that solar minima could have induced changes in the stratosphere that favour the development of high-pressure blocking systems located to the south of Greenland, as has been found in observations and model simulations for recent climate(9,10). We conclude that the mechanism behind solar forcing of regional climate change may have been similar under both modern and Last Glacial Maximum climate conditions.

Department/s

  • Quaternary Sciences
  • MERGE: ModElling the Regional and Global Earth system
  • BECC: Biodiversity and Ecosystem services in a Changing Climate

Publishing year

2014

Language

English

Pages

662-666

Publication/Series

Nature Geoscience

Volume

7

Issue

9

Document type

Journal article

Publisher

Nature Publishing Group

Topic

  • Geology

Status

Published

ISBN/ISSN/Other

  • ISSN: 1752-0908