Northern lakes are important sources of the climate forcing trace gases methane (CH4) and carbon dioxide (CO2). A substantial portion of lakes' annual emissions can take place immediately after ice melt in spring. The drivers of these fluxes are neither well constrained nor fully understood. We present a detailed carbon gas budget for three subarctic lakes, using 6 years of eddy covariance and 9 years of manual flux measurements. We combine measurements of temperature, dissolved oxygen, and CH4 stable isotopologues to quantify functional relationships between carbon gas production and conversion, energy inputs, and the redox regime. Spring emissions were regulated by the availability of oxygen in winter, rather than temperature as during ice‐free conditions. Under‐ice storage increased predictably with ice‐cover duration, and CH4 accumulation rates (25 ± 2 mg CH4‐C·m−2·day−1) exceeded summer emissions (19 ± 1 mg CH4‐C·m−2·day−1). The seasonally ice‐covered lakes emitted 26–59% of the annual CH4 flux and 15–30% of the annual CO2 flux at ice‐off. Reduced spring emissions were associated with winter snowmelt events, which can transport water downstream and oxygenate the water column. Stable isotopes indicate that 64–96% of accumulated CH4 escaped oxidation, implying that a considerable portion of the dissolved gases produced over winter may evade to the atmosphere.
Abstract. Ecosystems exchange climate-relevant trace gases with the atmosphere,
including volatile organic compounds (VOCs) that are a small but highly
reactive part of the carbon cycle. VOCs have important ecological functions
and implications for atmospheric chemistry and climate. We measured the
ecosystem-level surface–atmosphere VOC fluxes using the eddy covariance
technique at a shallow subarctic lake and an adjacent graminoid-dominated
fen in northern Sweden during two contrasting periods: the peak growing
season (mid-July) and the senescent period post-growing season
(September–October). In July, the fen was a net source of methanol, acetaldehyde, acetone, dimethyl sulfide,
isoprene, and monoterpenes. All of these VOCs showed a diel cycle of
emission with maxima around noon and isoprene dominated the fluxes (93±22 µmol m−2 d−1, mean ± SE). Isoprene
emission was strongly stimulated by temperature and presented a steeper
response to temperature (Q10=14.5) than that typically assumed in
biogenic emission models, supporting the high temperature sensitivity of
arctic vegetation. In September, net emissions of methanol and isoprene were
drastically reduced, while acetaldehyde and acetone were deposited to the
fen, with rates of up to -6.7±2.8 µmol m−2 d−1 for acetaldehyde. Remarkably, the lake was a sink for acetaldehyde and acetone during both
periods, with average fluxes up to -19±1.3 µmol m−2 d−1 of acetone in July and up to -8.5±2.3 µmol m−2 d−1 of acetaldehyde in September. The deposition of
both carbonyl compounds correlated with their atmospheric mixing ratios,
with deposition velocities of -0.23±0.01 and -0.68±0.03 cm s−1 for acetone and acetaldehyde, respectively. Even though these VOC fluxes represented less than 0.5 % and less than
5 % of the CO2 and CH4 net carbon ecosystem exchange,
respectively, VOCs alter the oxidation capacity of the atmosphere. Thus,
understanding the response of their emissions to climate change is important
for accurate prediction of the future climatic conditions in this rapidly
warming area of the planet.
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