DataSheet1_Effects of long-term climate trends on the methane and CO2 exchange processes of Toolik Lake, Alaska.pdf

Methane and carbon dioxide effluxes from aquatic systems in the Arctic will affect and likely amplify global change. As permafrost thaws in a warming world, more dissolved organic carbon (DOC) and greenhouse gases are produced and move from soils to surface waters where the DOC can be oxidized to CO...

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Bibliographic Details
Main Authors: Werner Eugster, Tonya DelSontro, James A. Laundre, Jason Dobkowski, Gaius R. Shaver, George W. Kling
Format: Dataset
Language:unknown
Published: 2022
Subjects:
Environmental Science
Climate Science
Environmental Impact Assessment
Environmental Management
Soil Biology
Water Treatment Processes
Environmental Engineering Design
Environmental Engineering Modelling
Environmental Technologies
Toolik Lake
long-term ecological research
LTER
methane flux
carbon dioxide flux
piston velocity
arctic trends
quantile regression
Arctic
Arctic Lake
Ice
permafrost
Tundra
Alaska
Online Access:https://doi.org/10.3389/fenvs.2022.948529.s001
https://figshare.com/articles/dataset/DataSheet1_Effects_of_long-term_climate_trends_on_the_methane_and_CO2_exchange_processes_of_Toolik_Lake_Alaska_pdf/21085570
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Summary:Methane and carbon dioxide effluxes from aquatic systems in the Arctic will affect and likely amplify global change. As permafrost thaws in a warming world, more dissolved organic carbon (DOC) and greenhouse gases are produced and move from soils to surface waters where the DOC can be oxidized to CO 2 and also released to the atmosphere. Our main study objective is to measure the release of carbon to the atmosphere via effluxes of methane (CH 4 ) and carbon dioxide (CO 2 ) from Toolik Lake, a deep, dimictic, low-arctic lake in northern Alaska. By combining direct eddy covariance flux measurements with continuous gas pressure measurements in the lake surface waters, we quantified the k 600 piston velocity that controls gas flux across the air–water interface. Our measured k values for CH 4 and CO 2 were substantially above predictions from several models at low to moderate wind speeds, and only converged on model predictions at the highest wind speeds. We attribute this higher flux at low wind speeds to effects on water-side turbulence resulting from how the surrounding tundra vegetation and topography increase atmospheric turbulence considerably in this lake, above the level observed over large ocean surfaces. We combine this process-level understanding of gas exchange with the trends of a climate-relevant long-term (30 + years) meteorological data set at Toolik Lake to examine short-term variations (2015 ice-free season) and interannual variability (2010–2015 ice-free seasons) of CH 4 and CO 2 fluxes. We argue that the biological processing of DOC substrate that becomes available for decomposition as the tundra soil warms is important for understanding future trends in aquatic gas fluxes, whereas the variability and long-term trends of the physical and meteorological variables primarily affect the timing of when higher or lower than average fluxes are observed. We see no evidence suggesting that a tipping point will be reached soon to change the status of the aquatic system from gas source to sink. We estimate ...

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