Landscape influence on permafrost ground ice geochemistry in a polar desert environment, Resolute Bay, Nunavut

Arctic permafrost is degrading and is thus releasing nutrients, solutes, sediment and water into soils and freshwater ecosystems. The impacts of this degradation depends on the geochemical characteristics and in large part on the spatial distribution of ground ice and solutes, which is not well-know...

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Bibliographic Details
Published in:Arctic Science
Main Authors: Michel Paquette, Melissa J. Lafrenière, Scott F. Lamoureux
Format: Article in Journal/Newspaper
Language:English
French
Published: Canadian Science Publishing 2023
Subjects:
ground ice
permafrost
polar desert
geochemistry
geomorphology
glace de sol
Environmental sciences
GE1-350
Environmental engineering
TA170-171
Arctic
Nunavut
Resolute Bay
Ice
Online Access:https://doi.org/10.1139/as-2021-0049
https://doaj.org/article/a33fb6d2a9ad48f68273f13ecf5df417
Description
Summary:Arctic permafrost is degrading and is thus releasing nutrients, solutes, sediment and water into soils and freshwater ecosystems. The impacts of this degradation depends on the geochemical characteristics and in large part on the spatial distribution of ground ice and solutes, which is not well-known in the High Arctic polar desert ecosystems. This research links ground ice and solute concentrations, to establish a framework for identifying locations vulnerable to permafrost degradation. It builds on landscape classifications and cryostratigraphic interpretations of permafrost history. Well-vegetated wetland sites with syngenetic permafrost aggradation show a different geochemical signature from polar desert and epigenetic sites. In wetlands, where ground ice contents were high (<97% volume), total dissolved solute concentrations were relatively low (mean 283.0 ± 327.8 ppm), reflecting a carbonate terrestrial/freshwater setting. In drier sites with epigenetic origin, such as polar deserts, ice contents are low (<47% volume), solute concentrations were high (mean 3248.5 ± 1907.0 ppm, max 12055 ppm) and dominated by Na+ and Cl− ions, reflecting a post-glacial marine inundation during permafrost formation. Dissolved organic carbon and total dissolved nitrogen concentrations usually increased at the top of permafrost and could not be as clearly associated with permafrost history. The research shows that the geochemistry of polar desert permafrost is highly dependent on permafrost history, and it can be estimated using hydrogeomorphological terrain classifications. The lower ice content of polar desert sites indicates that these areas are more vulnerable to thaw relative to the ice-rich wetland sites, and the elevated solute concentrations indicate that these areas could mobilise substantial solutes to downstream environments, should they become hydrologically connected with future warming.

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