Abstract
Abstract. Dryness stress is expected to become a more common problem in central European forests due to the predicted regional climate change. Forest management has to adapt to climate change in time and think ahead several decades in decisions on which tree species to plant at which locations. The summer of 2003 was the most severe dryness event in recent time, but more periods like this are expected. Since forests on different sites react quite differently to drought conditions, we used the process-based growth model BiomeBGC and climate time series from sites all over Germany to simulate the reaction of deciduous and coniferous tree stands in different characteristics of drought stress. Times with exceptionally high values of water vapour pressure deficit coincided with negative modelled values of net primary production (NPP). In addition, in these warmest periods the usually positive relationship between temperature and NPP was inversed, i.e., under stress conditions, more sunlight does not lead to more photosynthesis but to stomatal closure and reduced productivity. Thus we took negative NPP as an indicator for drought stress. In most regions, 2003 was the year with the most intense stress, but the results were quite variable regionally. We used the Modis MOD17 gross and net primary production product time series and MOD12 land cover classification to validate the spatial patterns observed in the model runs and found good agreement between modelled and observed behaviour. Thus, BiomeBGC simulations with realistic site parameterization and climate data in combination with species- and variety-specific ecophysiological constants can be used to assist in decisions on which trees to plant on a given site.
Highlights
Dryness stress is expected to become a more common problem in central European forests due to the predicted regional climate change
A model of bio-geo-chemical cycles that simulates, among other variables, water states, plant photosynthesis, gross primary productivity (GPP), and net primary productivity (NPP) based on site and climate data is expected to show the effects of dryness periods on forest trees, so that decisions on which trees to cultivate on which sites can be aided
There is a positive correlation between temperature and NPP most of the time, since high temperatures are correlated with high irradiance and high photosynthesis
Summary
Dryness stress is expected to become a more common problem in central European forests due to the predicted regional climate change. Forest management has to adapt to climate change in time and think ahead several decades in decisions on which tree species to plant at which locations. Forest management is facing the challenge of having to decide on the best tree species and variations to plant on each site for the climate of future decades. A model of bio-geo-chemical cycles that simulates, among other variables, water states, plant photosynthesis, gross primary productivity (GPP), and net primary productivity (NPP) based on site and climate data is expected to show the effects of dryness periods on forest trees, so that decisions on which trees to cultivate on which sites can be aided. The model is not designed for single-tree considerations or for managed forests, but can be adapted for these (Cienciala and Tatarinov, 2006; Tatarinov and Cienciala, 2006; Schlerf et al, 2005). Adaptations have been made for successional change (Bond-Lamberty et al, 2005), for hydrological changes (Pietsch et al, 2003), and for dynamic mortality (Pietsch and Hasenauer, 2006)
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