Annual layering in the NGRIP ice core during the Eemian

Research output: Contribution to journalJournal articleResearchpeer-review

Standard

Annual layering in the NGRIP ice core during the Eemian. / Svensson, Anders; Bigler, Matthias; Kettner, Ernesto; Dahl-Jensen, Dorthe; Johnsen, Sigfus Johann; Kipfstuhl, Sepp; Nielsen, Maibritt; Steffensen, Jørgen Peder.

In: Climate of the Past, Vol. 7, 16.12.2011, p. 1427.

Research output: Contribution to journalJournal articleResearchpeer-review

Harvard

Svensson, A, Bigler, M, Kettner, E, Dahl-Jensen, D, Johnsen, SJ, Kipfstuhl, S, Nielsen, M & Steffensen, JP 2011, 'Annual layering in the NGRIP ice core during the Eemian', Climate of the Past, vol. 7, pp. 1427.

APA

Svensson, A., Bigler, M., Kettner, E., Dahl-Jensen, D., Johnsen, S. J., Kipfstuhl, S., Nielsen, M., & Steffensen, J. P. (2011). Annual layering in the NGRIP ice core during the Eemian. Climate of the Past, 7, 1427.

Vancouver

Svensson A, Bigler M, Kettner E, Dahl-Jensen D, Johnsen SJ, Kipfstuhl S et al. Annual layering in the NGRIP ice core during the Eemian. Climate of the Past. 2011 Dec 16;7:1427.

Author

Svensson, Anders ; Bigler, Matthias ; Kettner, Ernesto ; Dahl-Jensen, Dorthe ; Johnsen, Sigfus Johann ; Kipfstuhl, Sepp ; Nielsen, Maibritt ; Steffensen, Jørgen Peder. / Annual layering in the NGRIP ice core during the Eemian. In: Climate of the Past. 2011 ; Vol. 7. pp. 1427.

Bibtex

@article{f4ecd0ad2d98461494e1dc9d1ba1d801,
title = "Annual layering in the NGRIP ice core during the Eemian",
abstract = "The Greenland NGRIP ice core continuously covers the period from present day back to 123 ka before present, which includes several thousand years of ice from the previous interglacial period, MIS 5e or the Eemian. In the glacial part of the core, annual layers can be identified from impurity records and visual stratigraphy, and stratigraphic layer counting has been performed back to 60 ka. In the deepest part of the core, however, the ice is close to the pressure melting point, the visual stratigraphy is dominated by crystal boundaries, and annual layering is not visible to the naked eye. In this study, we apply a newly developed setup for high-resolution ice core impurity analysis to produce continuous records of dust, sodium and ammonium concentrations as well as conductivity of melt water. We analyzed three 2.2m sections of ice from the Eemian and the glacial inception. In all of the analyzed ice, annual layers can clearly be recognized, most prominently in the dust and conductivity profiles. Part of the samples is, however, contaminated in dust, most likely from drill liquid. It is interesting that the annual layering is preserved despite a very active crystal growth and grain boundary migration in the deep and warm NGRIP ice. Based on annual layer counting of the new records, we determine a mean annual layer thickness close to 11mm for all three sections, which, to first order, confirms the modeled NGRIP time scale (ss09sea). The counting does, however, suggest a longer duration of the climatically warmest part of the NGRIP record (MIS5e) of up to 1 ka as compared to the model estimate. Our results suggest that stratigraphic layer counting is possible basically throughout the entire NGRIP ice core, provided sufficiently highly-resolved profiles become available.",
author = "Anders Svensson and Matthias Bigler and Ernesto Kettner and Dorthe Dahl-Jensen and Johnsen, {Sigfus Johann} and Sepp Kipfstuhl and Maibritt Nielsen and Steffensen, {J{\o}rgen Peder}",
year = "2011",
month = dec,
day = "16",
language = "English",
volume = "7",
pages = "1427",
journal = "Climate of the Past",
issn = "1814-9324",
publisher = "Copernicus GmbH",

}

RIS

TY - JOUR

T1 - Annual layering in the NGRIP ice core during the Eemian

AU - Svensson, Anders

AU - Bigler, Matthias

AU - Kettner, Ernesto

AU - Dahl-Jensen, Dorthe

AU - Johnsen, Sigfus Johann

AU - Kipfstuhl, Sepp

AU - Nielsen, Maibritt

AU - Steffensen, Jørgen Peder

PY - 2011/12/16

Y1 - 2011/12/16

N2 - The Greenland NGRIP ice core continuously covers the period from present day back to 123 ka before present, which includes several thousand years of ice from the previous interglacial period, MIS 5e or the Eemian. In the glacial part of the core, annual layers can be identified from impurity records and visual stratigraphy, and stratigraphic layer counting has been performed back to 60 ka. In the deepest part of the core, however, the ice is close to the pressure melting point, the visual stratigraphy is dominated by crystal boundaries, and annual layering is not visible to the naked eye. In this study, we apply a newly developed setup for high-resolution ice core impurity analysis to produce continuous records of dust, sodium and ammonium concentrations as well as conductivity of melt water. We analyzed three 2.2m sections of ice from the Eemian and the glacial inception. In all of the analyzed ice, annual layers can clearly be recognized, most prominently in the dust and conductivity profiles. Part of the samples is, however, contaminated in dust, most likely from drill liquid. It is interesting that the annual layering is preserved despite a very active crystal growth and grain boundary migration in the deep and warm NGRIP ice. Based on annual layer counting of the new records, we determine a mean annual layer thickness close to 11mm for all three sections, which, to first order, confirms the modeled NGRIP time scale (ss09sea). The counting does, however, suggest a longer duration of the climatically warmest part of the NGRIP record (MIS5e) of up to 1 ka as compared to the model estimate. Our results suggest that stratigraphic layer counting is possible basically throughout the entire NGRIP ice core, provided sufficiently highly-resolved profiles become available.

AB - The Greenland NGRIP ice core continuously covers the period from present day back to 123 ka before present, which includes several thousand years of ice from the previous interglacial period, MIS 5e or the Eemian. In the glacial part of the core, annual layers can be identified from impurity records and visual stratigraphy, and stratigraphic layer counting has been performed back to 60 ka. In the deepest part of the core, however, the ice is close to the pressure melting point, the visual stratigraphy is dominated by crystal boundaries, and annual layering is not visible to the naked eye. In this study, we apply a newly developed setup for high-resolution ice core impurity analysis to produce continuous records of dust, sodium and ammonium concentrations as well as conductivity of melt water. We analyzed three 2.2m sections of ice from the Eemian and the glacial inception. In all of the analyzed ice, annual layers can clearly be recognized, most prominently in the dust and conductivity profiles. Part of the samples is, however, contaminated in dust, most likely from drill liquid. It is interesting that the annual layering is preserved despite a very active crystal growth and grain boundary migration in the deep and warm NGRIP ice. Based on annual layer counting of the new records, we determine a mean annual layer thickness close to 11mm for all three sections, which, to first order, confirms the modeled NGRIP time scale (ss09sea). The counting does, however, suggest a longer duration of the climatically warmest part of the NGRIP record (MIS5e) of up to 1 ka as compared to the model estimate. Our results suggest that stratigraphic layer counting is possible basically throughout the entire NGRIP ice core, provided sufficiently highly-resolved profiles become available.

M3 - Journal article

VL - 7

SP - 1427

JO - Climate of the Past

JF - Climate of the Past

SN - 1814-9324

ER -

ID: 35936748