Global climate change threatens ecosystem functioning worldwide. Forest ecosystems are particularly important for carbon sequestration. However, recurrent stresses, such as heat waves, floods, and droughts, increasingly endanger even central European forests, with potentially cascading effects on their carbon sink capacity, drought resilience, and sustainability. Knowledge on the impact on the multitude of processes driving soil-plant-atmosphere interactions within these complex systems is widely lacking and uncertainty about future changes extremely high. Thus, forecasting forest response to climate change will require an improved process understanding of carbon and water cycling across various temporal and spatial scales, from minutes to seasons, from leaves to ecosystem, covering the atmosphere, biosphere, pedosphere and hydrosphere. Many relevant processes occur at small scales and high spatial heterogeneity and their interactions and feed-back loops can be key players to amplify or dampen a system’s response to stress. Currently, we are lacking the appropriate measuring, data and modelling tools allowing for comprehensive, real time quantification of relevant processes at high spatio-temporal coverage. Moreover, climate impacts are highly unpredictable, and thus future research will require novel mobile, easy deployable, and cost-efficient approaches.Our interdisciplinary research project ECOSENSE will investigate all relevant scales in a next generation ecosystem research assessment. Our vision is to detect and forecast critical changes in ecosystem functioning based on the understanding of hierarchical process interaction. To do so ECOSENSE will develop, implement, and test a new versatile, distributed, cost-effective, autonomous, intelligent sensor network based on novel microsensors tailored to the specific needs in remote and harsh forest environments. They will measure the spatio-temporal dynamics of ecosystem states and fluxes in a minimally invasive manner in naturally complex structured forests. Measured data will be transferred in real-time into a sophisticated database which can be explored for process analysis, deep learning approaches, and enhanced simulation models for now- and forecasting applications. ECOSENSE will open new horrizons for integrative ecosystem research by i) identifying hierarchies and interactions of abiotic and biotic processes of forest carbon and water exchange, ii) provide a profound understanding of complex ecosystem responses to environmental stressors enabling the iii) prediction of process-based alterations in ecosystem functioning and sustainability. Our novel ECOSENSE Toolkit, tested and validated in controlled climate extreme experiments, and our ECOSENSE Forest, will open new horizons for rapid assessment in vast and remote ecosystems.

DFG Programme Collaborative Research Centres

• A01 - Multifunctional and energy-autonomous soil probe systems for measuring carbon fluxes in the tree root environment (Project Heads Lang, Friederike ;  Schack-Kirchner, Helmer ;  Woias, Peter ;  Wöllenstein, Jürgen )
• A02 - Linking carbon and water fluxes in trees to the soil and atmosphere using in-situ NMR and ecohydrological sensor cluster (Project Heads Jouda, Ph.D., Mazin ;  Korvink, Jan Gerrit ;  Weiler, Markus ;  Werner, Christiane )
• A03 - An autonomous, multi-cuvettes laser-spectrometer system to study leaf photosynthetic isotope discrimination, CO2 exchange and volatile organic compound (VOC) emissions (Project Heads Haberstroh, Simon ;  Schmitt, Katrin ;  Wallrabe, Ulrike ;  Werner, Christiane )
• A04 - Process-based ecosystem-atmosphere exchange of CO2, H2O and volatile organic compounds (VOCs) (Project Heads Christen, Andreas ;  Kreuzwieser, Jürgen ;  Wöllenstein, Jürgen )
• B01 - Wireless, energy-autonomous chlorophyll fluorescence (ChlF) measurement in tree canopies using flexible, multifunctional and highly integrated microsensor probes (Project Heads Comella, Laura Maria ;  Rupitsch, Stefan J. ;  Werner, Christiane )
• B02 - Remote assessment of chlorophyll fluorescence (ChlF) as indicator for canopy vitality using UAVs with robust lightweight instrumentation (Project Heads Göritz, Anna ;  Koch, Barbara ;  Reiterer, Alexander ;  Wallrabe, Ulrike )
• C01 - Wireless, energy-autonomous and energy-aware embedded sensor systems (Project Heads Reindl, Leonhard Michael ;  Rupitsch, Stefan J. ;  Woias, Peter )
• C02 - Antibiofouling and Antisoiling Coatings (Project Heads Comella, Laura Maria ;  Prucker, Oswald ;  Rühe, Jürgen ;  Wallrabe, Ulrike ;  Woias, Peter )
• C04 - Deep-learning and process-based models for simulating carbon and water fluxes across scales (Project Heads Dormann, Carsten ;  Grote, Rüdiger ;  Kiese, Ralf )
• INFC03 - Data management (Project Head Weiler, Markus )
• MGKIRTG - Integrated Research Training Group (Project Heads Schmitt, Katrin ;  Woias, Peter )
• Z01 - Joint Research Platform (Project Heads Christen, Andreas ;  Wallrabe, Ulrike ;  Weiler, Markus ;  Werner, Christiane )
• Z02 - Administration and management of the CRC (Project Head Werner, Christiane )

Applicant Institution Albert-Ludwigs-Universität Freiburg

Participating Institution Karlsruher Institut für Technologie

Spokesperson Professorin Dr. Christiane Werner