Phenological mismatch in coastal western Alaska may increase summer season greenhouse gas uptake

High latitude ecosystems are prone to phenological mismatches due to climate change- driven advances in the growing season and changing arrival times of migratory herbivores. These changes have the potential to alter biogeochemical cycling and contribute to feedbacks on climate change by altering gr...

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Bibliographic Details
Published in:Environmental Research Letters
Main Authors: Katharine C Kelsey, A Joshua Leffler, Karen H Beard, Ryan T Choi, Joel A Schmutz, Jeffery M Welker
Format: Article in Journal/Newspaper
Language:English
Published: IOP Publishing 2018
Subjects:
Yukon Kuskokwim Delta
climate change
carbon dioxide
methane
nitrous oxide
trophic mismatch
Environmental technology. Sanitary engineering
TD1-1066
Environmental sciences
GE1-350
Science
Q
Physics
QC1-999
Arctic
Yukon
Climate change
Kuskokwim
Alaska
Online Access:https://doi.org/10.1088/1748-9326/aab698
https://doaj.org/article/e145c1a0a9714833b5d6c7cdde8c9b11
Description
Summary:High latitude ecosystems are prone to phenological mismatches due to climate change- driven advances in the growing season and changing arrival times of migratory herbivores. These changes have the potential to alter biogeochemical cycling and contribute to feedbacks on climate change by altering greenhouse gas (GHG) emissions of carbon dioxide (CO _2 ), methane (CH _4 ) and nitrous oxide (N _2 O) through large regions of the Arctic. Yet the effects of phenological mismatches on gas fluxes are currently unexplored. We used a three-year field experiment that altered the start of the growing season and timing of grazing to investigate how phenological mismatch affects GHG exchange. We found early grazing increased mean GHG emission to the atmosphere despite lower CH _4 emissions due to grazing-induced changes in vegetation structure that increased uptake of CO _2 . In contrast, late grazing reduced GHG emissions because greater plant productivity led to an increase in CO _2 uptake that overcame the increase in CH _4 emission. Timing of grazing was an important control on both CO _2 and CH _4 emissions, and net GHG exchange was the result of opposing fluxes of CO _2 and CH _4 . N _2 O played a negligible role in GHG flux. Advancing the growing season had a smaller effect on GHG emissions than changes to timing of grazing in this study. Our results suggest that a phenological mismatch that delays timing of grazing relative to the growing season, a change which is already developing along in western coastal Alaska, will reduce GHG emissions to the atmosphere through increased CO _2 uptake despite greater CH _4 emissions.

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