Prof. Dr. Kerstin Wiegand
Dr. Sasha Keyel
Dr. Rodolphe Sabatier
Project aim (lay audience)
Our primary goal is to understand where different species of plants are growing, why they are growing there, and what effects they may be having on the other plants and the soil. We will be using computer models with data from grassland plant species found in the three Biodiversity Exploratories in Germany. Specifically, we are interested in understanding more about how plant trait diversity, or the variety of characteristics found in the plants, affects the number of species in an area. We predict that greater plant trait diversity will allow greater species diversity.
For example, plant height is an example of a trait. We predict that two species of plants with different heights will be more likely to be able to coexist than two species of plants with the same height. The rationale is that one of the plants with the same height will out-compete the other. In contrast, for plants with two different heights, the shorter plant may be adapted to shade conditions, and therefore be able to coexist with the taller plant. We are looking at a variety of traits related to plant growth, reproduction, and regeneration.
We also expect that having a diversity of traits will be important under changing environmental conditions. For example, we know that land use and management patterns have changed, and are changing. In addition, the weather changes from year to year, and there long-term changes in climate. We think that communities (groups of species) with a greater diversity of traits, will have fewer species go extinct and will maintain ecosystem processes under changes in environmental conditions.
Finally, we want to know if we can take environmental information, such as temperature or rainfall, and predict what trait values will be present in an area. Using that information, we want to predict which species are likely to be present, and how their presence might change if either land use or climate changes.
Project aim (scientific audience)
Our primary goal is to integrate species distribution models into a metacommunity model based on functional traits to examine the relationships between trait diversity, long-term species richness, and ecosystem functioning in the context of changes in land use and changes in climate. Ultimately, we aim to have a model that has predictive power for community composition in real landscapes.
Specifically, we intend to
1) Fit species distribution models for grassland species in the Biodiversity Exploratories.
2) Develop a grassland metacommunity model.
3) Analyze the metacommunity model for theoretical settings investigating the relationship between response trait diversity and long-term species richness and ecosystem functioning. This will be done in the context of changing land use and changing climate.
4) Derive a predictive model for metacommunity composition.
We propose to test the following ecological hypotheses
E1.1: Species with high niche overlap or from different successional stages will have high reciprocal explanatory value in the species distribution models.
E2.1: Functional response trait diversity enhances the long-term maintenance of species richness, beta diversity, and productivity, i.e. “insurance effect”.
E2.2: Species beta-diversity increases with landscape fragmentation.
E2.3: The insurance effect of response trait diversity increases with landscape fragmentation.
E2.4: The insurance effect of response trait diversity increases with local environmental harshness and stochasticity (proxies for land-use intensity).
E3.1: Species with similar trait combinations have a similar spatial distribution.
E3.2: Functional trait diversity of the regional species pool is important for long-term ecosystem functioning and resilience to changing environmental conditions.
Finally, we propose to project species distributions into the future under different scenarios of land-use change and composition, and evaluate these projections.
Previous project phase (2008 - 2011)
In this cooperative project we aim for an understanding of the various mechanisms underlying the link between diversity and ecosystem function. To achieve this goal we will develop based on and as an expansion of Hubbell’s neutral theory, theoretical models to test the plausibility and scope of basic and general explanations for the diversity-function relationship. On the other hand we will design data-based mechanistic models which will allow to integrate existing and future data in such a way that important hypotheses about the link between diversity and ecosystem functioning can be evaluated.
PD Dr. Thomas Hovestadt
Our primary goal within Task 1 (PI Hovestadt) is to learn more about the principal mechanisms which lead to the establishment of certain diversity patterns. To achieve this we will use different theoretical and modelling approaches to test the plausibility and generality of alternative explanatory approaches. As a reference and null-model we will use Hubbel’s “neutral theory”. However, we will analyse the predictions of this theory for non-equilibrium conditions and expand it to apply to heterogeneous landscapes (forgoing the neutrality assumption). With the latter modification we also develop instruments to model the link between diversity and ecosystem function about which Hubbell’s theory does not make any predictions.
1. The correlation in diversity across different, non-interacting functional groups depends on the similarity in fundamental life-history attributes like life-expectancy, fertility, dispersal potential, resistance against disturbance, or specialization.
2. Diversity patterns and correlations of them across different functional groups are distinctly different in equilibrium and non-equilibrium phases, e.g. following habitat disturbances, landscape alternations, or during the invasion of new species.
3. Landscapes showing fine-grained habitat diversity are characterized by high alpha- but low beta- diversity and will be dominated by habitat generalists. Ecosystem functions will not be provided at optimum (maximum) level. Opposing predictions can be made for landscapes dominated by coarse grained habitat diversity.
Subproject 2: Towards a mechanistic understanding of biodiversity and its functional consequences - the Biodiversity Exploratory additional modeling component
Prof. Dr. Florian Jeltsch
Prof. Dr. Kerstin Wiegand
We seek to develop, test and apply novel grid-based mechanistic process models to simulate changes in plant functional trait (PFT) diversity in grassland succession in a regional context of land-use diversity. A bottom-up approach will be used to link mechanisms and processes acting at a local scale to the regional/landscape level.
Task 2 proceeds in three steps: In task 2.1, the small-scale, individual based, spatially-explicit PFT grassland model will be developed. In task 2.2, the model will be further developed into a patch-level state-and-transition grassland model. Finally, in task 2.3, the model will be linked with a landscape model, which provides the basis to further scale up to the regional level.
Subproject 3: Forest diversity and functioning in response to management and herbivory
PIs Prof. Dr. Christian Wirth, Dr. Markus Reichstein