Remote sensing evaluation of High Arctic wetland depletion following permafrost disturbance by thermo-erosion gullying processes

Northern wetlands and their productive tundra vegetation are of prime importance for Arctic wildlife by providing high-quality forage and breeding habitats. However, many wetlands are becoming drier as a function of climate-induced permafrost degradation. This phenomenon is notably the case in cold,...

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Bibliographic Details
Published in:Arctic Science
Main Authors: Naïm Perreault, Esther Lévesque, Daniel Fortier, Denis Gratton, Laurent J. Lamarque
Format: Article in Journal/Newspaper
Language:English
French
Published: Canadian Science Publishing 2017
Subjects:
arctic wetlands
thermo-erosion gullies
permafrost disturbance
remote sensing
normalized difference vegetation index (ndvi)
Environmental sciences
GE1-350
Environmental engineering
TA170-171
Arctic
Nunavut
Bylot Island
Ice
permafrost
Tundra
wedge*
Online Access:https://doi.org/10.1139/as-2016-0047
https://doaj.org/article/b0871671c95641bf8ef9ecaf07094409
Description
Summary:Northern wetlands and their productive tundra vegetation are of prime importance for Arctic wildlife by providing high-quality forage and breeding habitats. However, many wetlands are becoming drier as a function of climate-induced permafrost degradation. This phenomenon is notably the case in cold, ice-rich permafrost regions such as Bylot Island, Nunavut, where degradation of ice wedges and thermo-erosion gullying have already occurred throughout the polygon-patterned landscape resulting in a progressive shift from wet to mesic tundra vegetation within a decade. This study reports on the application of the normalized difference vegetation index to determine the extent of permafrost ecosystem disturbance on wetlands adjacent to thermo-erosion gullies. The analysis of a GeoEye-1 image of the Qarlikturvik valley, yielding a classification with five classes and 62% accuracy, resulted in directly identifying affected areas when compared to undisturbed baseline of wet and mesic plant communities. The total wetland area lost by drainage around the three studied gullies approximated to 95 430 m2, which already represents 0.5% of the total wetland area of the valley. This is worrisome considering that 36 gullies have been documented in a single valley since 1999 and that permafrost degradation by thermal erosion gullying is significantly altering landscape morphology, modifying wetland hydrology, and generating new fluxes of nutrients, sediments, and carbon in the watershed. This study demonstrates that remote sensing provides an effective means for monitoring spatially and temporally the impact of permafrost disturbance on Arctic wetland stability.

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