Tundra fire increases the likelihood of methane hotspot formation in the Yukon–Kuskokwim Delta, Alaska, USA

Rapid warming in Arctic tundra may lead to drier soils in summer and greater lightning ignition rates, likely culminating in enhanced wildfire risk. Increased wildfire frequency and intensity leads to greater conversion of permafrost carbon to greenhouse gas emissions. Here, we quantify the effect o...

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Bibliographic Details
Published in:Environmental Research Letters
Main Authors: Elizabeth Yoseph, Elizabeth Hoy, Clayton D Elder, Sarah M Ludwig, David R Thompson, Charles E Miller
Format: Article in Journal/Newspaper
Language:English
Published: IOP Publishing 2023
Subjects:
tundra
hotspots
Arctic
ABoVE
wildfire
YK Delta
Environmental technology. Sanitary engineering
TD1-1066
Environmental sciences
GE1-350
Science
Q
Physics
QC1-999
Yukon
Kuskokwim
permafrost
Tundra
Alaska
Online Access:https://doi.org/10.1088/1748-9326/acf50b
https://doaj.org/article/4c26fc468d194323893fa91330e21e9c
Description
Summary:Rapid warming in Arctic tundra may lead to drier soils in summer and greater lightning ignition rates, likely culminating in enhanced wildfire risk. Increased wildfire frequency and intensity leads to greater conversion of permafrost carbon to greenhouse gas emissions. Here, we quantify the effect of recent tundra fires on the creation of methane (CH _4 ) emission hotspots, a fingerprint of the permafrost carbon feedback. We utilized high-resolution (∼25 m ^2 pixels) and broad coverage (1780 km ^2 ) airborne imaging spectroscopy and maps of historical wildfire-burned areas to determine whether CH _4 hotspots were more likely in areas burned within the last 50 years in the Yukon–Kuskokwim Delta, Alaska, USA. Our observations provide a unique observational constraint on CH _4 dynamics, allowing us to map CH _4 hotspots in relation to individual burn events, burn scar perimeters, and proximity to water. We find that CH _4 hotspots are roughly 29% more likely on average in tundra that burned within the last 50 years compared to unburned areas and that this effect is nearly tripled along burn scar perimeters that are delineated by surface water features. Our results indicate that the changes following tundra fire favor the complex environmental conditions needed to generate CH _4 emission hotspots. We conclude that enhanced CH _4 emissions following tundra fire represent a positive feedback that will accelerate climate warming, tundra fire occurrence, and future permafrost carbon loss to the atmosphere.

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