Abstract
Climate warming and changing precipitation patterns have thermally (active layer deepening) and physically (permafrost-thaw related mass movements) disturbed permafrost-underlain watersheds across much of the Arctic, increasing the transfer of dissolved and particulate material from terrestrial to aquatic ecosystems. We examined the multiyear (2006–2017) impact of thermal and physical permafrost disturbances on all of the major components of fluvial flux. Thermal disturbances increased the flux of dissolved organic carbon (DOC), but localized physical disturbances decreased multiyear DOC flux. Physical disturbances increased major ion and suspended sediment flux, which remained elevated a decade after disturbance, and changed carbon export from a DOC to a particulate organic carbon (POC) dominated system. As the magnitude and frequency of physical permafrost disturbance intensifies in response to Arctic climate change, disturbances will become an increasingly important mechanism to deliver POC from terrestrial to aquatic ecosystems. Although nival runoff remained the primary hydrological driver, the importance of pluvial runoff as driver of fluvial flux increased following both thermal and physical permafrost disturbance. We conclude the transition from a nival-dominated fluvial regime to a regime where rainfall runoff is proportionately more important will be a likely tipping point to accelerated High Arctic change.
Highlights
Climate warming and changing precipitation patterns have thermally and physically disturbed permafrost-underlain watersheds across much of the Arctic, increasing the transfer of dissolved and particulate material from terrestrial to aquatic ecosystems
We focus on two small headwater slope streams within the West river watershed: Ptarmigan (PT; 0.21 k m2) and Goose (GS; 0.18 km2) (Fig. 1b)
Multiyear thermal disturbance increased the seasonal flux of dissolved organic carbon (DOC) from a small thermally disturbed, but physically undisturbed watershed at the Cape Bounty Arctic Watershed Observatory (CBAWO) (Fig. 5a)
Summary
Climate warming and changing precipitation patterns have thermally (active layer deepening) and physically (permafrost-thaw related mass movements) disturbed permafrost-underlain watersheds across much of the Arctic, increasing the transfer of dissolved and particulate material from terrestrial to aquatic ecosystems. Multiple pan-Arctic studies show that observed climate change is already transferring significant quantities of terrestrial material to downstream aquatic e cosystems[8,9,10] as a physical response to increases in the magnitude, frequency, and type of permafrost disturbance[11,12,13,14]. Quantifying the multiyear response of both DOC and POC export to differing forms of permafrost disturbance is crucial for understanding controls on the transfer of organic carbon (OC) from terrestrial surfaces to aquatic ecosystems in a changing Arctic climate[20,35,36,37]
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