Your search keyword '"Kjær, Kurt H."' showing total 4 results

1. Cosmogenic nuclide inheritance in Little Ice Age moraines - A case study from Greenland

Author

Larsen, Nicolaj K., Søndergaard, Anne Sofie, Levy, Laura B., Laursen, Charlotte H., Bjørk, Anders A., Kjeldsen, Kristian K., Funder, Svend, Strunk, Astrid, Olsen, Jesper, and Kjær, Kurt H.

Published

2021

2. Glacier response to the Little Ice Age during the Neoglacial cooling in Greenland.

Author

Kjær, Kurt H., Bjørk, Anders A., Kjeldsen, Kristian K., Hansen, Eric S., Andresen, Camilla S., Siggaard-Andersen, Marie-Louise, Khan, Shfaqat A., Søndergaard, Anne Sofie, Colgan, William, Schomacker, Anders, Woodroffe, Sarah, Funder, Svend, Rouillard, Alexandra, Jensen, Jens Fog, and Larsen, Nicolaj K.

Subjects

*MELTWATER, *LITTLE Ice Age, *GLACIERS, *GREENLAND ice, *ICE sheets, *ICE cores, *ICE caps, *COOLING

Abstract

In the Northern Hemisphere, an insolation driven Early to Middle Holocene Thermal Maximum was followed by a Neoglacial cooling that culminated during the Little Ice Age (LIA). Here, we review the glacier response to this Neoglacial cooling in Greenland. Changes in the ice margins of outlet glaciers from the Greenland Ice Sheet as well as local glaciers and ice caps are synthesized Greenland-wide. In addition, we compare temperature reconstructions from ice cores, elevation changes of the ice sheet across Greenland and oceanographic reconstructions from marine sediment cores over the past 5,000 years. The data are derived from a comprehensive review of the literature supplemented with unpublished reports. Our review provides a synthesis of the sensitivity of the Greenland ice margins and their variability, which is critical to understanding how Neoglacial glacier activity was interrupted by the current anthropogenic warming. We have reconstructed three distinct periods of glacier expansion from our compilation: two older Neoglacial advances at 2,500 – 1,700 yrs. BP (Before Present = 1950 CE, Common Era) and 1,250 – 950 yrs. BP; followed by a general advance during the younger Neoglacial between 700-50 yrs. BP, which represents the LIA. There is still insufficient data to outline the detailed spatio-temporal relationships between these periods of glacier expansion. Many glaciers advanced early in the Neoglacial and persisted in close proximity to their present-day position until the end of the LIA. Thus, the LIA response to Northern Hemisphere cooling must be seen within the wider context of the entire Neoglacial period of the past 5,000 years. Ice expansion appears to be closely linked to changes in ice sheet elevation, accumulation, and temperature as well as surface-water cooling in the surrounding oceans. At least for the two youngest Neoglacial advances, volcanic forcing triggering a sea-ice /ocean feedback, could explain their initiation. There are probably several LIA glacier fluctuations since the first culmination close to 1250 CE (Common Era) and available data suggests ice culminations in the 1400s, early to mid-1700s and early to mid-1800s CE. The last LIA maxima lasted until the present deglaciation commenced around 50 yrs. BP (1900 CE). The constraints provided here on the timing and magnitude of LIA glacier fluctuations delivers a more realistic background validation for modelling future ice sheet stability. [ABSTRACT FROM AUTHOR]

Published

2022

3. Persistence of Holocene ice cap in northeast Svalbard aided by glacio-isostatic rebound.

Author

Farnsworth, Wesley R., Ingólfsson, Ólafur, Brynjólfsson, Skafti, Allaart, Lis, Kjellman, Sofia E., Kjær, Kurt H., Larsen, Nicolaj K., Macias-Fauria, Marc, Siggaard-Andersen, Marie-Louise, and Schomacker, Anders

Subjects

*ICE caps, *HOLOCENE Epoch, *SEA ice, *ICE sheets, *GLOBAL warming, *ISOSTASY, *GLACIERS

Abstract

The deglaciation of the Svalbard-Barents Sea Ice Sheet was driven by relative sea-level rise, the incursion of North Atlantic waters around Spitsbergen, and increasing summer insolation. However, ice retreat was interrupted by asynchronous re-advances that occurred into high relative seas, during a period associated with warm regional waters and elevated summer temperatures. Better understanding of this complex style of deglaciation and the dynamic response to a warming climate can serve as an important analogue for modern warming and today's ice sheets. We present evidence from northern Svalbard of glacier re-advances during the Late Glacial-Early Holocene in hand with relative sea-level history and the occurrence of thermophilous molluscs. We argue that glacio-isostatic adjustment during the transition into the Holocene influenced ice marginal dynamics and as a result, the southern region of the Åsgardfonna ice cap persisted through the Holocene Thermal Maximum. • Asynchronous tributary glacier re-advances during the transition from Late Glacial to Early Holocene. • Tidewater glacier margin survives Holocene Thermal Maximum alongside thermophilous molluscs. • Glacier sustenance aided by glacio-isostatic adjustment. [ABSTRACT FROM AUTHOR]

Published

2024

4. Holocene ice margin variations of the Greenland Ice Sheet and local glaciers around Sermilik Fjord, southeast Greenland.

Author

Larsen, Nicolaj K., Siggaard-Andersen, Marie-Louise, Bjørk, Anders A., Kjeldsen, Kristian K., Ruter, Anthony, Korsgaard, Niels J., and Kjær, Kurt H.

Subjects

*GREENLAND ice, *ICE sheets, *HOLOCENE Epoch, *ICE caps, *FJORDS, *GLACIERS, *ALPINE glaciers, *MELTWATER

Abstract

Understanding the long-term difference in the response times of ice sheets, peripheral ice caps and glaciers may provide information about their respective sensitivities to climate change. However, there are only a few places where the history of local glaciers, ice caps (GICs) and the Greenland Ice Sheet (GrIS) have been recorded in the same area. In this study, we use proglacial threshold lake records from four sites around Sermilik Fjord, in southeast Greenland to determine the Holocene ice marginal variations. Combined with other published records from the area, we find that the GrIS margin receded to within its present extent in the Early Holocene ~9.6 cal ka BP, probably reaching its minimum extent by ~7.3 to 6.3 cal ka BP before readvancing to its maximum Late Holocene position between ~2.6 and 0.3 cal ka BP. The GICs began to retreat ~9.5 cal ka BP and completely melted away for an extended period between ~8 and 4 ka during the Middle Holocene. Regrowth of the GICs began during the early- and late Neoglacial and they reached their maximum extent between ~1.2 and 0.7 cal ka BP. In general, we find a coherent pattern of ice marginal variations between the GrIS and GICs, which coincides with the major Holocene climate changes. However, our results also demonstrate that there are differences in the synchronicity between individual records, which largely are dictated by the local topography that determines when ice marginal changes were recorded in proglacial lakes. Accordingly, this study illustrates both the advantages and limitations of the method and highlight the need for multiple proglacial lake records to constrain past glacier variations in a region. [ABSTRACT FROM AUTHOR]

Published

2022