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Interactions Among Abiotic Drivers,Disturbance and Gross Ecosystem Carbon Exchange on Soil Respiration from Subtropical Pine Savannas
Authors:Susanne Wiesner  Christina L. Staudhammer  Henry W. Loescher  Andres Baron-Lopez  Lindsay R. Boring  Robert J. Mitchell  Gregory Starr
Affiliation:1.Department of Biological Sciences,University of Alabama,Tuscaloosa,USA;2.Battelle - National Ecological Observatory Network (NEON),Boulder,USA;3.Institute of Alpine and Arctic Research,University of Colorado,Boulder,USA;4.Jones Ecological Research Center,Newton,USA;5.Odum School of Ecology,University of Georgia,Athens,USA
Abstract:
Globally, soil CO2 efflux rates (Fs) have been linked to changes in soil water content (SWC), rainfall and temperature and/or productivity. However, within an ecosystem, Fs can vary based on site structure and function, which can be affected by a combination of abiotic and biotic factors. This becomes particularly important when an ecosystem is faced with disturbances, such as drought or fire. Site-specific compensatory responses to disturbances may therefore alter C mineralization, as well as root respiration. Hence, single location Fs estimates may not be a representative for ecosystems across their distributional ranges. We conducted a 6-year study along an edaphic moisture gradient of longleaf pine ecosystems that were maintained with prescribed fire, using eddy covariance and soil respiration measurements to address how Fs varies with changes in ecosystem structure and function, as well as disturbances. Lower air temperatures (Tair) decreased Fs at all sites, but that response was also affected by productivity and SWC. Productivity significantly altered Fs rates at all sites, especially when we accounted for changes in temperature and SWC. Plant regrowth post-fire temporarily increased Fs (10–40%), whereas drought reduced Fs at all sites. Our results show that site productivity, Fs and the degree to which ecosystems adapt to climate variations and disturbance can be site specific. Hence, model forecasting of carbon dynamics would strongly benefit from multi-location measurements of Fs across the distributional range of an ecosystem.
Keywords:
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