Abstract
Arctic landscapes are experiencing intense warming and modification of precipitation regimes with climate change. Permafrost disturbances and climate change impacts on hydrology of Arctic watersheds are likely to modify the quantity and composition of exported dissolved organic matter (DOM). In July 2007, intense rainfall and active layer thickening caused widespread active layer detachments at Cape Bounty, Melville Island (Canada). This study investigates the impacts of seasonal hydrology and permafrost disturbance on DOM composition exported from High Arctic headwater catchments. In 2012, streams were sampled from three disturbed catchments and one undisturbed catchment. The composition of DOM was characterized using absorbance and fluorescence spectroscopy. DOM was mostly exported during the spring freshet. Throughout this period, the undisturbed catchment exported humified DOM with high humic-like fluorescence that likely originated from runoff through shallow organic rich soil. In contrast, DOM exported from disturbed catchments was fresher, less humified with a high proportion of low molecular weight humic acid. We demonstrate that disturbed catchments delivered likely more labile DOM derived from either thawed permafrost or enhanced microbial activity. If this labile DOM comes from an ancient pool, as indicated by other studies at this site, disturbances may strengthen the permafrost carbon feedback on climate change.
Highlights
Climate change is faster in the Arctic than elsewhere on the globe and is expected to intensify in the future (IPCC 2013)
This research aims to determine the impacts of seasonal hydrology and permafrost disturbance on the composition of dissolved organic matter (DOM) exported from High Arctic headwater catchments using absorbance and fluorescence measurements
This study reports on the seasonal evolution of DOM composition in water streams from an undisturbed catchment (GS) and three catchments (CR, ALD and PT) that were subject to increasing degrees of disturbance, in a High-Arctic watershed
Summary
Climate change is faster in the Arctic than elsewhere on the globe and is expected to intensify in the future (IPCC 2013) Climate models project both ground warming and increased precipitation in the High Arctic (Guido et al 2016). The composition and the biodegradability of riverine DOM is controlled by 1) the nature of vegetation and soil organic matter (Ward and Cory 2015), 2) sorption processes in soil mineral layers (Kawahigashi et al 2006) and 3) biodegradation and photodegradation occurring within soils and rivers (Mann et al 2012; Olefeldt et al 2013). DOM in Arctic rivers represents one of the most active pools of terrestrial carbon (Vonk et al 2015), its fate with deeper thaw and permafrost degradation is still uncertain (Frey and McClelland 2009). It is crucial to better understand how the composition of exported DOM varies temporally and https://mc06.manuscriptcentral.com/asopen-pubs
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