Degradation of ice-wedge polygons leads to increased fluxes of water and DOC

Ice-wedge polygon landscapes make up a substantial part of high-latitude permafrost landscapes. The hydrological conditions shape how these landscapes store and release organic carbon. However, their coupled water‑carbon dynamics are poorly understood as field measurements are sparse in smaller catc...

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Bibliographic Details
Published in:Science of The Total Environment
Main Authors: Speetjens, Niek Jesse, Berghuijs, Wouter R., Wagner, Julia, Vonk, Jorien E.
Format: Article in Journal/Newspaper
Language:English
Published: 2024
Subjects:
Dissolved organic carbon
Hydrology
Ice-wedge polygon
Lateral carbon flux
Model
Permafrost
Arctic
Canada
Yukon
Ice
permafrost
wedge*
Online Access:https://research.vu.nl/en/publications/5c356b6b-1a5d-4984-937a-5a41482140bd
https://doi.org/10.1016/j.scitotenv.2024.170931
https://hdl.handle.net/1871.1/5c356b6b-1a5d-4984-937a-5a41482140bd
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Summary:Ice-wedge polygon landscapes make up a substantial part of high-latitude permafrost landscapes. The hydrological conditions shape how these landscapes store and release organic carbon. However, their coupled water‑carbon dynamics are poorly understood as field measurements are sparse in smaller catchments and coupled hydrology-dissolved organic carbon (DOC) models are not tailored for these landscapes. Here we present a model that simulates the hydrology and associated DOC export of high-centered and low-centered ice-wedge polygons and apply the model to a small catchment with abundant polygon coverage along the Yukon Coast, Canada. The modeled seasonal pattern of water and carbon fluxes aligns with sparse field data. These modeled seasonal patterns indicate that early-season runoff is mostly surficial and generated by low-centered polygons and snow trapped in troughs of high-centered polygons. High-centered polygons show potential for deeper subsurface flow under future climate conditions. This suggests that high-centered polygons will be responsible for an increasing proportion of annual DOC export compared to low-centered polygons. Warming likely shifts low-centered polygons to high-centered polygons, and our model shows that this shift will cause a deepening of the active layer and a lengthening of the thawing season. This, in turn, intensifies seasonal runoff and DOC flux, mainly through its duration. Our model provides a physical hypothesis that can be used to further quantify and refine our understanding of hydrology and DOC export of arctic ice-wedge polygon terrain.

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