Project Details
Feedbacks between Biodiversity and Climate
Subject Area
Ecology and Biodiversity of Plants and Ecosystems
Term
since 2020
Project identifier
Deutsche Forschungsgemeinschaft (DFG) - Project number 451398802
Terrestrial ecosystems, through the cycling of energy, water, elements, and trace gases, are important determinants of climate. While impacts of climate on biodiversity has been extensively studied, little is known about the effects of biodiversity on climate and to what degree this feedback can mitigate or increase the degree to which climate is shifting. Here, we set a specific focus on the feedback of biodiversity to the climate and to nature’s contributions to people. This will allow for a better understanding of the cascading effects and feedback loops of global environmental change. A major limitation for solving this issue is the fact that climate or earth system models use a very simple parametrization scheme of biodiversity to date. These schemes only differentiate between very broad vegetation categories, such as broadleaved and needle leaved forest or plant functional types. Such a simple classification of the functional diversity is not capable of well representing the processes relevant to address biodiversity feedbacks to the atmosphere. In this project, we will use two dynamic vegetation models DVMs; FATE-HD and LPJ-Guess, in combination with two climate models: COSMO-CLM2 and CHELSA to create coupled biodiversity-climate scenarios for the historical period and for two emission scenarios (rcp2.6, rcp8.5). The problem of limited vegetation classes will be overcome by calculating biodiversity and vegetation processes and effects at a much finer scale than is calculated for climate. We apply a fine scale classification of vegetation (EUNIS) and additionally parameterize biodiversity and functional trait diversity. Biodiversity effects on the climate in these models will be parametrized by 1) integrating vegetation databases (sPlot and the European Vegetation Archive, EVA) in combination with remotely sensed data from Sentinel and Landsat and downscaled climate data from COSMO-CLM2. The information from these vegetation databases will also be used to run the DVMs at unprecedented spatial detail (100m across the Alps, 5km across Europe). Aggregating this information to the climate model scale (12 km) will then allow the DVMs to provide information back to the COSMO-CLM2 through a calibration process by which physico-structural and biogeochemical properties are passed to the climate model. The effect of biodiversity on climate will then be investigated by either excluding specific biodiversity relevant variables or randomizing them in the model. This will allow us to quantify their effect on the entire ecosystem–climate system across entire Europe for the past and the future. Furthermore, the information from the detected biodiversity–climate feedbacks will directly be linked to Nature’s contribution to people using an ecosystem services framework. By this will help to better mitigate climate change effects and to better communicate biodiversity–climate feedbacks for climate-smart biodiversity and NCP management to stakeholders.
DFG Programme
Research Grants
International Connection
Czech Republic, France, Sweden, Switzerland