Paleorecords of Antarctic ice motion, subglacial hydrology, and chemical weathering

With more than 70m of sea level equivalent ice stored in the polar ice sheets, sea level forecasting is heavily reliant on projections of ice sheet response to changes in global climate. One way that Earth scientists have approached this problem is to look back at past warm periods to determine how...

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Bibliographic Details
Main Author: Piccione, Gavin Gerard
Other Authors: Blackburn, Terrence J
Format: Thesis
Language:English
Published: eScholarship, University of California 2023
Subjects:
Geology
Geochemistry
Paleoclimate science
Antarctica
Paleoclimatology
U-Series Geochronology
Antarctic
The Antarctic
Antarc*
Ice Sheet
Online Access:https://escholarship.org/uc/item/54f6c8rt
Description
Summary:With more than 70m of sea level equivalent ice stored in the polar ice sheets, sea level forecasting is heavily reliant on projections of ice sheet response to changes in global climate. One way that Earth scientists have approached this problem is to look back at past warm periods to determine how terrestrial ice mass changed in during previous climatic events. In Antarctic, however, there is an added complexity that 97.6% of the modern continent is covered by ice, which restricts access to the geologic record. Without terrestrial archives of Antarctic ice sheet evolution, it is challenging to parameterize the dominant processes that govern ice sheet sensitivity to climate and the environmental effects of ice loss. In this dissertation, I applied geochronologic, isotopic, elemental, and spectroscopic analyses to Antarctic subglacial chemical precipitates – a novel terrestrial record of basal conditions – to investigate the processes that link climate change, Antarctic ice motion, and the hydrologic system at the ice-bed interface. Collectively, this work expands our understanding of Antarctic evolution on centennial to millennial timescales and establishes Antarctic subglacial precipitates as climate archives analogous to speleothems.The first two chapters investigate the physical processes associated with subglacial hydrology and ice motion. By applying geochronologic and geochemical analyses to a group of precipitates that formed over tens-of-thousands of years during the Late Pleistocene, we showed that the continent-wide Antarctic subglacial hydrologic system responds rapidly (within 60 yrs.) to millennial-scale climate events, with more intense subglacial flushing during warm periods and diminished basal meltwater flow during cold periods. This close coupling between climate and subglacial hydrologic activity requires changes to Antarctic ice surface slope caused by hundreds of meters of thinning at the ice sheet margins. These studies provide evidence that the Antarctic gains and loses ice during ...

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