Three-dimensional subsurface architecture and its influence on the spatiotemporal development of a retrogressive thaw slump in the Richardson Mountains, Northwest Territories, Canada

The development of retrogressive thaw slumps (RTS) is known to be strongly influenced by relief-related parameters, permafrost characteristics, and climatic triggers. To deepen the understanding of RTS, this study examines the subsurface characteristics in the vicinity of an active thaw slump, locat...

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Bibliographic Details
Published in:Arctic, antarctic, and alpine research antarctic, and alpine research, 2023-12, Vol.55 (1)
Main Authors: Kunz, Julius, Ullmann, T., Kneisel, C., Baumhauer, R.
Format: Article
Language:English
Subjects:
Active layer
Antarctic region
Arctic region
Canada
Digital Elevation Models
Digital imaging
electrical resistance
Electrical resistivity
frost
Ground penetrating radar
Hydrology
Image resolution
Mountains
near-surface geophysics
Permafrost
Radar
remote sensing
Retrogressive thaw slump
runoff
Satellite imagery
spatiotemporal slump development
Thickness
tomography
topography
Unmanned aerial vehicles
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Summary:The development of retrogressive thaw slumps (RTS) is known to be strongly influenced by relief-related parameters, permafrost characteristics, and climatic triggers. To deepen the understanding of RTS, this study examines the subsurface characteristics in the vicinity of an active thaw slump, located in the Richardson Mountains (Western Canadian Arctic). The investigations aim to identify relationships between the spatiotemporal slump development and the influence of subsurface structures. Information on these were gained by means of electrical resistivity tomography (ERT) and ground-penetrating radar (GPR). The spatiotemporal development of the slump was revealed by high-resolution satellite imagery and unmanned aerial vehicle-based digital elevation models (DEMs). The analysis indicated an acceleration of slump expansion, especially since 2018. The comparison of the DEMs enabled the detailed balancing of erosion and accumulation within the slump area between August 2018 and August 2019. In addition, manual frost probing and GPR revealed a strong relationship between the active layer thickness, surface morphology, and hydrology. Detected furrows in permafrost table topography seem to affect the active layer hydrology and cause a canalization of runoff toward the slump. The three-dimensional ERT data revealed a partly unfrozen layer underlying a heterogeneous permafrost body. This may influence the local hydrology and affect the development of the RTS. The results highlight the complex relationships between slump development, subsurface structure, and hydrology and indicate a distinct research need for other RTSs.
ISSN:1523-0430
1938-4246
1938-4246
DOI:10.1080/15230430.2023.2167358