Explaining temporal variation in soil CO 2 efflux in a mature spruce forest in Southern Germany

Abstract

An open dynamic chamber system was used to measure the soil CO 2 efflux intensively and continuously throughout a growing season in a mature spruce forest ( Picea abies) in Southern Germany. The resulting data set contained a large amount of temporally highly resolved information on the variation in soil CO 2 efflux together with environmental variables. Based on this background, the dependencies of the soil CO 2 efflux rate on the controlling environmental factors were analysed in-depth. Of the abiotic factors, soil temperature alone explained 72% of the variation in the efflux rate, and including soil water content (SWC) as an additional variable increased the explained variance to about 83%. Between April and December, average rates ranged from 0.43 to 5.15 μmol CO 2 m −2 s −1 (in November and July, respectively) with diurnal variations of up to 50% throughout the experiment. The variability in wind speed above the forest floor influenced the CO 2 efflux rates for measuring locations with a litter layer of relatively low bulk density (and hence relatively high proportions of pore spaces). For the temporal integration of flux rates for time scales of hours to days, however, wind velocities were of no effect, reflecting the fact that wind forcing acts on the transport, but not the production of CO 2 in the soil. The variation in both the magnitude of the basal respiration rate and the temperature sensitivity throughout the growing season was only moderate (coefficient of variation of 15 and 25%, respectively). Soil water limitation of the CO 2 production in the soil could be best explained by a reduction in the temperature-insensitive basal respiration rate, with no discernible effect on the temperature sensitivity. Using a soil CO 2 efflux model with soil temperature and SWC as driving variables, it was possible to calculate the annual soil CO 2 efflux for four consecutive years for which meteorological data were available. These simulations indicate an average efflux sum of 560 g C m −2 yr −1 (SE=22 g C m −2 yr −1). An alternative model derived from the same data but using temperature alone as a driver over-estimated the annual flux sum by about 7% and showed less inter-annual variability. Given a likely shift in precipitation patterns alongside temperature changes under projected global change scenarios, these results demonstrate the necessity to include soil moisture in models that calculate the evolution of CO 2 from temperate forest soils.