Abstract
In a warming Arctic, permafrost-related disturbances, such as retrogressive thaw slumps (RTS), are becoming more abundant and dynamic, with serious implications for permafrost stability and bio-geochemical cycles on local to regional scales. Despite recent advances in the field of earth observation, many of these have remained undetected as RTS are highly dynamic, small, and scattered across the remote permafrost region. Here, we assessed the potential strengths and limitations of using deep learning for the automatic segmentation of RTS using PlanetScope satellite imagery, ArcticDEM and auxiliary datasets. We analyzed the transferability and potential for pan-Arctic upscaling and regional cross-validation, with independent training and validation regions, in six different thaw slump-affected regions in Canada and Russia. We further tested state-of-the-art model architectures (UNet, UNet++, DeepLabv3) and encoder networks to find optimal model configurations for potential upscaling to continental scales. The best deep learning models achieved mixed results from good to very good agreement in four of the six regions (maxIoU: 0.39 to 0.58; Lena River, Horton Delta, Herschel Island, Kolguev Island), while they failed in two regions (Banks Island, Tuktoyaktuk). Of the tested architectures, UNet++ performed the best. The large variance in regional performance highlights the requirement for a sufficient quantity, quality and spatial variability in the training data used for segmenting RTS across diverse permafrost landscapes, in varying environmental conditions. With our highly automated and configurable workflow, we see great potential for the transfer to active RTS clusters (e.g., Peel Plateau) and upscaling to much larger regions.
Highlights
The changing climate of the Arctic, with both measured and projected air temperatures and precipitation rapidly increasing [1,2], has a significant impact on permafrost [3,4,5].As permafrost soils store about twice the amount of carbon as that found in the atmosphere [6,7], permafrost thaw and resulting carbon feedbacks are expected to have a significant impact on the global climate [8]
Retrogressive thaw slumps (RTS) are typical landforms related to processes of rapidly thawing and degrading hillslope permafrost [10]
For our model architecture we evaluated some network architectures commonly used for semantic segmentation
Summary
The changing climate of the Arctic, with both measured and projected air temperatures and precipitation rapidly increasing [1,2], has a significant impact on permafrost [3,4,5].As permafrost soils store about twice the amount of carbon as that found in the atmosphere [6,7], permafrost thaw and resulting carbon feedbacks are expected to have a significant impact on the global climate [8]. The changing climate of the Arctic, with both measured and projected air temperatures and precipitation rapidly increasing [1,2], has a significant impact on permafrost [3,4,5]. Rising permafrost ground temperatures have been observed across almost the entire Arctic permafrost region [3]. Retrogressive thaw slumps (RTS) are typical landforms related to processes of rapidly thawing and degrading hillslope permafrost [10]. These mass-wasting processes have been observed in different Arctic regions in the past decades [11,12,13], many recent
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