Surface water inundation in the boreal-Arctic: potential impacts on regional methane emissions

Northern wetlands may be vulnerable to increased carbon losses from methane (CH _4 ), a potent greenhouse gas, under current warming trends. However, the dynamic nature of open water inundation and wetting/drying patterns may constrain regional emissions, offsetting the potential magnitude of methan...

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Bibliographic Details
Published in:Environmental Research Letters
Main Authors: Jennifer D Watts, John S Kimball, Annett Bartsch, Kyle C McDonald
Format: Article in Journal/Newspaper
Language:English
Published: IOP Publishing 2014
Subjects:
Arctic
wetlands
permafrost
inundation
methane
microwave remote sensing
Environmental technology. Sanitary engineering
TD1-1066
Environmental sciences
GE1-350
Science
Q
Physics
QC1-999
Canada
Alaska
Online Access:https://doi.org/10.1088/1748-9326/9/7/075001
https://doaj.org/article/0539a6799e3f496095c95c6011e67809
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Summary:Northern wetlands may be vulnerable to increased carbon losses from methane (CH _4 ), a potent greenhouse gas, under current warming trends. However, the dynamic nature of open water inundation and wetting/drying patterns may constrain regional emissions, offsetting the potential magnitude of methane release. Here we conduct a satellite data driven model investigation of the combined effects of surface warming and moisture variability on high northern latitude (⩾45° N) wetland CH _4 emissions, by considering (1) sub-grid scale changes in fractional water inundation (Fw) at 15 day, monthly and annual intervals using 25 km resolution satellite microwave retrievals, and (2) the impact of recent (2003–11) wetting/drying on northern CH _4 emissions. The model simulations indicate mean summer contributions of 53 Tg CH _4 yr ^−1 from boreal-Arctic wetlands. Approximately 10% and 16% of the emissions originate from open water and landscapes with emergent vegetation, as determined from respective 15 day Fw means or maximums, and significant increases in regional CH _4 efflux were observed when incorporating satellite observed inundated land fractions into the model simulations at monthly or annual time scales. The satellite Fw record reveals widespread wetting across the Arctic continuous permafrost zone, contrasting with surface drying in boreal Canada, Alaska and western Eurasia. Arctic wetting and summer warming increased wetland emissions by 0.56 Tg CH _4 yr ^−1 compared to the 2003–11 mean, but this was mainly offset by decreasing emissions (−0.38 Tg CH _4 yr ^−1 ) in sub-Arctic areas experiencing surface drying or cooling. These findings underscore the importance of monitoring changes in surface moisture and temperature when assessing the vulnerability of boreal-Arctic wetlands to enhanced greenhouse gas emissions under a shifting climate.

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