Abstract
Abstract. High Arctic landscapes are essentially vast cold deserts interspersed with streams, ponds and wetlands. These landscapes may be important consumers and sources of the greenhouse gas methane (CH4), though few measurements exist from this region. To quantify the flux of CH4 (FCH4) between the atmosphere and high Arctic landscapes on northern Ellesmere Island, Canada, we made static chamber measurements over five and three growing seasons at a desert and wetland, respectively, and eddy covariance (EC) measurements at a wetland in 2012. Chamber measurements revealed that, during the growing season, desert soils consumed CH4 (−1.37 ± 0.06 mg-CH4 m−2 d−1), whereas the wetland margin emitted CH4 (+0.22 ± 0.14 mg-CH4 m−2 d−1). Desert CH4 consumption rates were positively associated with soil temperature among years, and were similar to temperate locations, likely because of suitable landscape conditions for soil gas diffusion. Wetland FCH4 varied closely with stream discharge entering the wetland and hence extent of soil saturation. Landscape-scale FCH4 measured by EC was +1.27 ± 0.18 mg-CH4 m−2 d−1 and varied with soil temperature and carbon dioxide flux. FCH4 measured using EC was higher than using chambers because EC measurements incorporated a larger, more saturated footprint of the wetland. Using EC FCH4 and quantifying the mass of CH4 entering and exiting the wetland in stream water, we determined that methanogenesis within wetland soils was the dominant source of FCH4. Low FCH4 at the wetland was likely due to a shallow organic soil layer, and thus limited carbon resources for methanogens. Considering the prevalence of dry soils in the high Arctic, our results suggest that these landscapes cannot be overlooked as important consumers of atmospheric CH4.
Highlights
Rapid warming is altering polar regions at unprecedented rates (AMAP, 2012)
Warming and wetting of the Arctic has resulted in several environmental responses, including permafrost thaw (Froese et al, 2008), glacial and sea ice melt (Pfeffer et al, 2008), increased surface runoff (Peterson et al, 2002), increased primary productivity and vegetation cover (Walker et al, 2006), and enhanced cycling of greenhouse gases (GHGs), including the powerful GHG methane (CH4; O’Connor et al, 2010), between the atmosphere and changing landscapes
When comparing paired sampling dates from each site between 2010 and 2012, we found that the desert landscape consumed significantly more atmospheric CH4 than the wetland (Repeated-measures ANOVA; F(1,17) =92, p < 0.001; Fig. 3). These site differences in flux of CH4 (FCH4) were related to the large differences in soil moisture and soil temperature (Fig. 3)
Summary
Rapid warming is altering polar regions at unprecedented rates (AMAP, 2012). Recent climate models suggest that Arctic mean annual temperatures will rise 2.5–7 ◦C by the end of the 21st century (Overland et al, 2011) but up to 9 ◦C in local regions such as the Canadian Arctic Archipelago (ACIA, 2005). Warming and wetting of the Arctic has resulted in several environmental responses, including permafrost thaw (Froese et al, 2008), glacial and sea ice melt (Pfeffer et al, 2008), increased surface runoff (Peterson et al, 2002), increased primary productivity and vegetation cover (Walker et al, 2006), and enhanced cycling of greenhouse gases (GHGs), including the powerful GHG methane (CH4; O’Connor et al, 2010), between the atmosphere and changing landscapes Both CH4 production (methanogenesis) and consumption (CH4 oxidation, or methanotrophy) occur in Arctic terrestrial, freshwater and marine ecosystems. In the low and high Arctic (as defined by AMAP, 1998), there are numerous sources of CH4 to the atmosphere, most of which are predicted to Published by Copernicus Publications on behalf of the European Geosciences Union
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