We analysed the effect of the 2018 European drought on greenhouse gas (GHG) exchange of five North European mire ecosystems. The low precipitation and high summer temperatures in Fennoscandia led to a lowered water table in the majority of these mires. This lowered both carbon dioxide (CO
2
) uptake and methane (CH
4
) emission during 2018, turning three out of the five mires from CO
2
sinks to sources. The calculated radiative forcing showed that the drought-induced changes in GHG fluxes first resulted in a cooling effect lasting 15–50 years, due to the lowered CH
4
emission, which was followed by warming due to the lower CO
2
uptake.
This article is part of the theme issue ‘Impacts of the 2018 severe drought and heatwave in Europe: from site to continental scale’.
Climate warming is anticipated to make high latitude ecosystems stronger C sinks through increasing plant production. This effect might, however, be dampened by insect herbivores whose damage to plants at their background, non-outbreak densities may more than double under climate warming. Here, using an open-air warming experiment among Subarctic birch forest field layer vegetation, supplemented with birch plantlets, we show that a 2.3°C air and 1.2°C soil temperature increase can advance the growing season by 1-4 days, enhance soil N availability, leaf chlorophyll concentrations and plant growth up to 400%, 160% and 50% respectively, and lead up to 122% greater ecosystem CO 2 uptake potential. However, comparable positive effects are also found when insect herbivory is reduced, and the effect of warming on C sink potential is intensified under reduced herbivory. Our results confirm the expected warming-induced increase in high latitude plant growth and CO 2 uptake, but also reveal that herbivorous insects may significantly dampen the strengthening of the CO 2 sink under climate warming.
Abstract. The patterned microtopography of subarctic mires generates a variety of
environmental conditions, and carbon dioxide (CO2) and methane
(CH4) dynamics vary spatially among different plant community types
(PCTs). We studied the CO2 and CH4 exchange between a subarctic
fen and the atmosphere at Kaamanen in northern Finland based on flux chamber
and eddy covariance measurements in 2017–2018. We observed strong spatial
variation in carbon dynamics between the four main PCTs studied, which were
largely controlled by water table level and differences in vegetation
composition. The ecosystem respiration (ER) and gross primary productivity
(GPP) increased gradually from the wettest PCT to the drier ones, and both
ER and GPP were larger for all PCTs during the warmer and drier growing
season 2018. We estimated that in 2017 the growing season CO2 balances
of the PCTs ranged from −20 g C m−2 (Trichophorum tussock PCT) to 64 g C m−2
(string margin PCT), while in 2018 all PCTs were small CO2 sources
(10–22 g C m−2). We observed small growing season CH4 emissions
(< 1 g C m−2) from the driest PCT, while the other three PCTs
had significantly larger emissions (mean 7.9, range 5.6–10.1 g C m−2)
during the two growing seasons. Compared to the annual CO2 balance
(−8.5 ± 4.0 g C m−2) of the fen in 2017, in 2018 the annual
balance (−5.6 ± 3.7 g C m−2) was affected by an earlier onset of
photosynthesis in spring, which increased the CO2 sink, and a drought
event during summer, which decreased the sink. The CH4 emissions were
also affected by the drought. The annual CH4 balance of the fen was 7.3 ± 0.2 g C m−2 in 2017 and 6.2 ± 0.1 g C m−2 in 2018.
Thus, the carbon balance of the fen was close to zero in both years. The PCTs that were adapted to drier conditions provided ecosystem-level resilience to carbon loss due to water level drawdown.
Abstract. The patterned microtopography of subarctic mires generates a variety of environmental conditions, and carbon dioxide (CO2) and methane (CH4) dynamics vary spatially among different plant community types. We studied the CO2 and CH4 exchange between a subarctic fen and the atmosphere at Kaamanen in northern Finland based on flux chamber and eddy covariance measurements in 2017–2018. We observed strong spatial variation in carbon dynamics between the four main plant community types (PCTs) studied, which were largely controlled by water table level and differences in vegetation composition. The ecosystem respiration (ER) and gross primary productivity (GPP) increased gradually from the wettest PCT to the drier ones, and both ER and GPP were larger for all PCTs during the warmer and drier growing season 2018. We estimated that in 2017 the growing season CO2 balances of the PCTs ranged from −20 g C m−2 (Trichophorum tussock PCT) to 64 g C m−2 (string margin PCT), while in 2018 all PCTs were small CO2 sources (10–22 g C m−2). We observed small growing season CH4 emission sums (
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