Unusually Warm Spring Temperatures Magnify Annual CH4 Losses From Arctic Ecosystems

Abstract:

The relatively fast pace of Northern high latitude warming puts the very large permafrost soil C pool at a higher risk of being lost to the atmosphere as CH₄. Estimates for the Arctic tundra’s contribution to the global wetland CH₄ emissions range from 15-27 TgCH₄ y^-1 (8-14% of total). However, these estimates are largely based on data from the growing season, or from boreal systems underlain by discontinuous permafrost with different physical, hydrological, and biogeochemical dynamics than continuous permafrost zones. Recent data from a transect of eddy covariance flux towers across the North Slope of Alaska revealed the importance of cold season emissions to the annual CH₄ budget, which may not correlate with summer flux patterns. However, understanding of the controls and inter-annual variability in fluxes at these different sites is lacking. Here, we present data from ~3 years at 5 tundra ecosystems along this Arctic transect to show the influence of earlier and deeper spring active layer thaw on timing and magnitude of CH₄ fluxes. This year’s warm spring led to significantly greater thaw depths and lower water tables than the previous year. Substantial CH₄ emissions in 2015 were recorded at the wettest sites >20 days earlier than in the more meteorologically normal previous year. Since the soil remained saturated despite a lowered water table, total spring CH₄ emissions more than doubled at these wet sites. At the drier sites, soil moisture declined with water table during the warmer spring, resulting in similar emissions to the previous year. However, deeper thaw depths prolonged fall and early winter emissions during the ‘zero-curtain’ soil temperature freezing phase, particularly at the drier site. In general, warmer spring temperatures in the Arctic may result in large increases in early season CH₄ losses at wet sites and prolonged steady losses at the upland sites, enhancing the feedback between changing climate and tundra CH₄ emissions at all sites.