Your search keyword '"Kirchner, Nina"' showing total 3 results

1. Simulated last deglaciation of the Barents Sea Ice Sheet primarily driven by oceanic conditions.

Author

Petrini, Michele, Colleoni, Florence, Kirchner, Nina, Hughes, Anna L.C., Camerlenghi, Angelo, Rebesco, Michele, Lucchi, Renata G., Forte, Emanuele, Colucci, Renato R., Noormets, Riko, and Mangerud, Jan

Subjects

*SEA ice, *ICE sheets, *GLACIAL melting, *CLIFFS, *LAST Glacial Maximum, *MELTWATER, *ANTARCTIC ice, *SUBGLACIAL lakes, *WEATHER

Abstract

The Barents Sea Ice Sheet was part of an interconnected complex of ice sheets, collectively referred to as the Eurasian Ice Sheet, which covered north-westernmost Europe, Russia and the Barents Sea during the Last Glacial Maximum (around 21 ky BP). Due to common geological features, the Barents Sea component of this ice complex is seen as a paleo-analogue for the present-day West Antarctic Ice Sheet. Investigating key processes driving the last deglaciation of the Barents Sea Ice Sheet represents an important tool to interpret recent observations in Antarctica over the multi-millennial temporal scale of glaciological changes. We present results from a perturbed physics ensemble of ice sheet model simulations of the last deglaciation of the Barents Sea Ice Sheet, forced with transient atmospheric and oceanic conditions derived from AOGCM simulations. The ensemble of transient simulations is evaluated against the data-based DATED-1 reconstruction to construct minimum, maximum and average deglaciation scenarios. Despite a large model/data mismatch at the western and eastern ice sheet margins, the simulated and DATED-1 deglaciation scenarios agree well on the timing of the deglaciation of the central and northern Barents Sea. We find that the simulated deglaciation of the Barents Sea Ice Sheet is primarily driven by the oceanic forcing, with prescribed eustatic sea level rise amplifying the ice sheet sensitivity to sub-shelf melting over relatively short intervals. Our results highlight that the sub-shelf melting has a very strong control on the simulated grounding-line flux, showing that a slow, gradual ocean warming trend is capable of triggering sustained grounded ice discharge over multi-millennial timescales, even without taking into account marine ice sheet or ice cliff instability. • We investigate the drivers of the last deglaciation of the Barents Sea Ice Sheet. • An ensemble of ice sheet model simulations is compared with data-based archives. • The simulated deglaciation is mainly driven by ocean warming. • Ocean warming can trigger sustained ice retreat over multi-millennial timescales. [ABSTRACT FROM AUTHOR]

Published

2020

2. Ice sheet retreat dynamics inferred from glacial morphology of the central Pine Island Bay Trough, West Antarctica

Author

Jakobsson, Martin, Anderson, John B., Nitsche, Frank O., Gyllencreutz, Richard, Kirshner, Alexandra E., Kirchner, Nina, O'Regan, Matthew, Mohammad, Rezwan, and Eriksson, Björn

Subjects

*ICE sheets, *GLACIAL climates, *GEOMORPHOLOGY, *LANDFORMS, *BATHYMETRIC maps

Abstract

Abstract: Pine Island Glacier drains portions of the West Antarctic Ice Sheet into the Amundsen Sea. During the Last Glacial Maximum the glacier extended nearly 500 km from its present location onto the outer continental shelf. Unusually restricted sea-ice cover during the austral summer of 2010 allowed for a systematic multibeam swath-bathymetric and chirp sonar survey of the mid-shelf section of Pine Island Trough. The mapped glacial landforms reveal new information about the paleo-Pine Island Ice Stream''s dynamic retreat from the mid-shelf area and confirm previous suggestion of a retreat in distinct steps. The periods of grounding line stability during the overall retreat phase are marked by sediment accumulations, i.e. grounding zone wedges. These wedges are here mapped in sufficient detail to characterize spatial dimensions and estimate the volume of deposited sediment. Considering a range of sediment flux rates from the paleo-Pine Island Ice Stream we estimate that the largest and most clearly defined grounding zone wedge, located at about 73°S in the surveyed area, took between 600 and 2000 years to form. The ice stream retreated landward of this wedge before 12.3 cal ka BP. The swath-bathymetric imagery of landforms in Pine Island Trough includes glacial features that suggest that retreat between periods of grounding line stability may be associated with episodes of ice shelf break-up. The depths of grounding line wedges decrease in a landward direction, from 740 to 670 m, and record elevation of the grounding line as it stepped landward. In all, the grounding line elevation varied by only ∼80 m over a distance of just over 100 km, implying a low ice sheet profile during retreat. Finally, we revisited seismic reflection profile NB9902, acquired along Pine Island Trough in 1999, in combination with the newly acquired swath-bathymetric imagery from 2010. Together these data show that the ice stream paused during its retreat to form grounding zone wedges at an area in central Pine Island Trough where a high in dipping bedrock strata exists and the glacial trough is narrow, forming a bathymetric “bottle neck”. [Copyright &y& Elsevier]

Published

2012

3. Geological record of ice shelf break-up and grounding line retreat, Pine Island Bay, West Antarctica.

Author

Jakobsson, Martin, Anderson, John B., Nitsche, Frank O., Dowdeswell, Julian A., Gyllencreutz, Richard, Kirchner, Nina, Mohammad, Rezwan, O'Regan, Matthew, Alley, Richard B., Anandakrishnan, Sridhar, Eriksson, Björn, Kirshner, Alexandra, Fernandez, Rodrigo, Stolldorf, Travis, Minzoni, Rebecca, and Majewski, Wojciech

Subjects

*ICE shelves, *BAYS, *GLACIOLOGY, *ICEBERGS, *SEA level, *OCEAN temperature

Abstract

The catastrophic break-ups of the floating Larsen A and B ice shelves (Antarctica) in 1995 and 2002 and associated acceleration of glaciers that flowed into these ice shelves were among the most dramatic glaciological events observed in historical time. This raises a question about the larger West Antarctic ice shelves. Do these shelves, with their much greater glacial discharge, have a history of collapse? Here we describe features from the seafloor in Pine Island Bay, West Antarctica, which we interpret as having been formed during a massive ice shelf break-up and associated grounding line retreat. This evidence exists in the form of seafloor landforms that we argue were produced daily as a consequence of tidally influenced motion of mega-icebergs maintained upright in an iceberg armada produced from the disintegrating ice shelf and retreating grounding line. The break-up occurred prior to ca. 12 ka and was likely a response to rapid sea-level rise or ocean warming at that time. [ABSTRACT FROM AUTHOR]

Published

2011