The project shall clarify the mechanisms that modulate streambed biogeochemistry (metabolism and nitrogen uptake of the microbial community) at various chronologies of flow resumption with and without sediment transport. The resumption of flow after drying is considered as a biogeochemical hot moment, with high rates of metabolism and nitrogen uptake influenced by the frequency of previous drying. The mechanisms modulating this hot moment are little known. Research so far were mostly single factor studies in temporary stream and river ecosystems. However intermittency and resumption of flow occurs increasingly also in perennial stream ecosystems and surface flow often implies sediment transport (e.g. migrating ripples, upper stage plane bed) especially in sandy streams. In addition, flow resumption can follow different chronologies such as instant by rain or slow by rising groundwater, and the concentrations of nutrient and carbon leached upon flow resumption can also influence the biogeochemical response. I suggest a new general concept of “intermittent stream habitats” for all areas of a streambed that dry (i.e. lack of surface water) at some point in time despite variable interactions of factors. The here proposed investigation of the mechanisms at various flow resumption chronologies, coupled sediment transport, and in temporary and perennial habitats will show if such general and integrative view can be applied. The interactions of flow resumption, sediment transport, nutrient and carbon concentrations and drying frequency will be studied in microcosm experiments with sediment communities of intermittent habitats from perennial and temporary streams. The response variables under attention are: Carbon metabolism, measured by means of changes in oxygen concentration in darkness and in light, net Nitrogen uptake by means of the addition of the stable isotope 15N (15NH4Cl) and the structure and architecture (i.e. biofilm) of the microbial community (just for coupled sediment transport). The results will contribute to a complete mechanistic picture of the Carbon and Nitrogen dynamics of lotic ecosystems prone to severe flow oscillations and drying. The findings will enable to incorporate flow resumption in the current concepts of stream biogeochemistry. Such conceptual framework is key for management of Mediterranean and more and more temperate stream ecosystems that experience drying due to increased water abstraction and climate change.

DFG Programme Research Grants

International Connection Israel, Italy, Spain

Cooperation Partners Dr. Maria Isabel Arce; Professor Dr. Shai Arnon; Dr. Rossano Bolpagni; Dr. Alex Laini

Co-Investigators Dr. Mario Brauns; Privatdozentin Dr. Ute Risse-Buhl