Extreme event impacts on CO2 fluxes across a range of high latitude, shrub-dominated ecosystems
Peer reviewed, Journal article
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Date
2020Metadata
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Original version
10.1088/1748-9326/abb0b1Abstract
The Arctic is experiencing an increased frequency of extreme events which can cause
landscape-scale vegetation damage. Extreme event-driven damage is an important driver of the
decline in vegetation productivity (termed ‘Arctic browning’) which has become an increasingly
important component of pan-Arctic vegetation change in recent years. A limited number of studies
have demonstrated that event-driven damage can have major impacts on ecosystem CO2 balance,
reducing ecosystem carbon sink strength. However, although there are many different extreme
events that cause Arctic browning and different ecosystem types that are affected, there is no
understanding of how impacts on CO2 fluxes might vary between these, or of whether
commonalities in response exist that would simplify incorporation of extreme event-driven Arctic
browning into models.
To address this, the impacts of different extreme events (frost-drought, extreme winter
warming, ground icing and a herbivore insect outbreak) on growing season CO2 fluxes of Net
Ecosystem Exchange (NEE), Gross Primary Productivity (GPP) and ecosystem respiration (Reco)
were assessed at five sites from the boreal to High Arctic (64◦N-79◦N) in mainland Norway and
Svalbard. Event-driven browning had consistent, major impacts across contrasting sites and event
drivers, causing site-level reductions of up to 81% of NEE, 51% of GPP and 37% of Reco.
Furthermore, at sites where plot-level NDVI (greenness) data were obtained, strong linear
relationships between NDVI and NEE were identified, indicating clear potential for impacts of
browning on CO2 balance to be consistently, predictably related to loss of greenness across
contrasting types of events and heathland ecosystems.
This represents the first attempt to compare the consequences of browning driven by different
extreme events on ecosystem CO2 balance, and provides an important step towards a better
understanding of how ecosystem CO2 balance will respond to continuing climate change at high
latitudes.