Evolution of Late Season Meltwater in Alpine and Arctic Glaciers: Sampling Strategies and Geochemical Observations

The presence, configuration, and efficiency of subglacial hydrologic systems has important implications for both glacial dynamics and the chemistry of meltwaters. These networks may exist in configurations that range from poorly connected and unable to accommodate large volumes of water to fast flow...

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Bibliographic Details
Main Author: Robbins, Mark
Other Authors: Hendy, Ingrid L, Bassis, Jeremy N, Blum, Joel D, Cole, Julia, Cory, Rose
Format: Thesis
Language:English
Subjects:
Glacial hydrochemistry
Subglacial drainage
Glacial seasonal evolution
Geology and Earth Sciences
Science
Arctic
Greenland
glacier
Ice Sheet
Online Access:https://hdl.handle.net/2027.42/155287
Description
Summary:The presence, configuration, and efficiency of subglacial hydrologic systems has important implications for both glacial dynamics and the chemistry of meltwaters. These networks may exist in configurations that range from poorly connected and unable to accommodate large volumes of water to fast flowing and highly competent in different regions of the glacial bed, simultaneously or in different seasons. Direct study of the configuration and development of these networks is difficult as they are obscured by ice, yet network configuration is important in glaciological research as it controls the spatial distribution and residence time of subglacial water. Subglacial network efficiency, or the ability of the network to quickly evacuate water, controls under-ice water-rock interaction time affecting chemical weathering reactions and thus solute type and concentration expressed in proglacial meltwaters. Previous research into the configuration of subglacial hydrologic networks is limited in both temporal and spatial resolution, as field research generally occurs during summer months and is limited to more easily accessible glaciers. This dissertation investigates seasonal changes in subglacial hydrologic networks as evidenced by changing meltwater chemistry in late-summer at both a Canadian alpine glacier and an outlet glacier from the Greenland Ice Sheet. I undertook multi-month field campaigns at each location, during which I collected samples and made in situ measurements to correlate changes in chemical constituents carried within melt to changes in seasonality, improving understanding of this understudied time in seasonal glacial development. This dissertation uses laboratory experiments with sediment samples collected at glacial termini to evaluate the use of radon-222 (222Rn) activity concentrations, an intermediary in the uranium-238 (238U) decay chain, as a proxy for subglacial water residence time. These measurements are compared to in field 222Rn activity concentration measurements at sediment collection ...

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