Scaling waterbody carbon dioxide and methane fluxes in the arctic using an integrated terrestrial-aquatic approach

In the Arctic waterbodies are abundant and rapid thaw of permafrost is destabilizing the carbon cycle and changing hydrology. It is particularly important to quantify and accurately scale aquatic carbon emissions in arctic ecosystems. Recently available high-resolution remote sensing datasets captur...

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Bibliographic Details
Published in:Environmental Research Letters
Main Authors: Sarah M Ludwig, Susan M Natali, John D Schade, Margaret Powell, Greg Fiske, Luke D Schiferl, Roisin Commane
Format: Article in Journal/Newspaper
Language:English
Published: IOP Publishing 2023
Subjects:
carbon
scaling
methane
lake
arctic
Environmental technology. Sanitary engineering
TD1-1066
Environmental sciences
GE1-350
Science
Q
Physics
QC1-999
Arctic
Methane Lake
permafrost
Online Access:https://doi.org/10.1088/1748-9326/acd467
https://doaj.org/article/650292b5767b491a9d8b311525c906f7
Description
Summary:In the Arctic waterbodies are abundant and rapid thaw of permafrost is destabilizing the carbon cycle and changing hydrology. It is particularly important to quantify and accurately scale aquatic carbon emissions in arctic ecosystems. Recently available high-resolution remote sensing datasets capture the physical characteristics of arctic landscapes at unprecedented spatial resolution. We demonstrate how machine learning models can capitalize on these spatial datasets to greatly improve accuracy when scaling waterbody CO _2 and CH _4 fluxes across the YK Delta of south-west AK. We found that waterbody size and contour were strong predictors for aquatic CO _2 emissions, attributing greater than two-thirds of the influence to the scaling model. Small ponds (<0.001 km ^2 ) were hotspots of emissions, contributing fluxes several times their relative area, but were less than 5% of the total carbon budget. Small to medium lakes (0.001–0.1 km ^2 ) contributed the majority of carbon emissions from waterbodies. Waterbody CH _4 emissions were predicted by a combination of wetland landcover and related drivers, as well as watershed hydrology, and waterbody surface reflectance related to chromophoric dissolved organic matter. When compared to our machine learning approach, traditional scaling methods that did not account for relevant landscape characteristics overestimated waterbody CO _2 and CH _4 emissions by 26%–79% and 8%–53% respectively. This study demonstrates the importance of an integrated terrestrial-aquatic approach to improving estimates and uncertainty when scaling C emissions in the arctic.

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